WO2022247571A1 - Method for switching virtual card, and electronic device - Google Patents

Abstract

The embodiments of the present application relate to the field of electronic devices. Disclosed are a method for switching a virtual card, and an electronic device, by means of which method and device the process of a user using a virtual card and swiping same is simplified, and the time consumption of card swiping is reduced, thereby improving the user experience. The specific solution comprises: when an electronic device completes data interaction at a first card swiping point by using a first virtual card for the first time, the electronic device acquiring GNSS position information and GNSS precision of the electronic device, wherein the first virtual card is a virtual card among a plurality of virtual cards; according to the GNSS position information and the GNSS precision, the electronic device establishing and storing a first GNSS fence corresponding to the first virtual card, wherein the first GNSS fence comprises a first fence and a second fence, and the range of the first fence is greater than that of the second fence; and when the electronic device detects that the position of the electronic device is in the range of the first GNSS fence, the electronic device activating the first virtual card.

Description

A virtual card switching method and electronic equipment

This application claims the priority of the Chinese patent application submitted to the State Intellectual Property Office on May 28, 2021, with the application number 202110592522.5, and the title of the invention is "A Switching Method for Near Field Communication NFC Cards", and filed on July 2021 The priority of a Chinese patent application filed with the State Intellectual Property Office on the 30th with the application number 202110875764.5 and the title of the invention "a virtual card switching method and electronic device", the entire content of which is incorporated in this application by reference.

technical field

The present application relates to the field of electronic equipment, in particular to a virtual card switching method and electronic equipment.

Background technique

Near field communication (near field communication, NFC) technology has been gradually extended to miniaturized electronic devices, such as mobile phones. In a mobile phone with NFC function, multiple NFC virtual cards can be configured, so that multiple functions such as bus card swiping, transaction payment, and access control unlocking can be realized.

However, when faced with different card swiping requirements, the user needs to manually select a virtual card, which makes the card swiping process more cumbersome and time-consuming.

Contents of the invention

Embodiments of the present application provide a virtual card switching method and an electronic device, which can simplify the process of swiping a card for a user, reduce time-consuming swiping a card, and thereby improve user experience.

In order to achieve the above purpose, the embodiment of the present application adopts the following technical solutions:

In a first aspect, the embodiment of the present application provides a virtual card switching method, which is applied to an electronic device, and the electronic device has an NFC function. The virtual card switching method may include: when the electronic device uses the first virtual card to complete data interaction at the first card swiping point for the first time, the electronic device obtains the GNSS position information and the GNSS accuracy of the electronic device; the first virtual card is a plurality of The virtual card in the virtual card; the electronic device establishes and stores the first GNSS fence corresponding to the first virtual card according to the GNSS position information and GNSS accuracy, the first GNSS fence includes the first fence and the second fence, and the first fence The range is larger than the range of the second fence; when the electronic device detects that the position of the electronic device is within the range of the first GNSS fence, the electronic device activates the first virtual card.

Based on the method described in the first aspect, when the electronic device uses a certain virtual card to complete a transaction at a certain card swiping point for the first time, according to the current GNSS position information of the electronic device, a GNSS geofence corresponding to the virtual card is established. Afterwards, when the user enters the range of the GNSS geo-fence again with the electronic device, the electronic device can automatically activate the virtual card corresponding to the GNSS geo-fence. Therefore, when faced with different card swiping requirements, the user can avoid manually selecting the virtual card that needs to be activated, thereby simplifying the process of the user swiping the card, reducing the duration of swiping the card, and improving user experience. Moreover, the solution of the present application is to establish a corresponding geographic fence based on the GNSS position information, and the GNSS position information can be obtained by using the short-distance chip of the electronic device. The short-distance chip is a standard configuration of electronic equipment, so even if the electronic equipment does not have the Wi-Fi fence capability, it can still realize the automatic activation of the corresponding virtual card before the user swipes the card, further improving the user experience. In addition, the solution of this application can accurately determine whether the user enters the range of the corresponding GNSS fence by establishing fences of different ranges corresponding to the virtual card, so that the electronic device can accurately identify the virtual card corresponding to the GNSS geographic fence entered by the user. activation.

In combination with the first aspect, in another possible implementation, the first fence is a circular area with the GNSS position information as the center and the preset length as the radius; the second fence is the GNSS position information as the center, A circular area with a radius of N times the GNSS precision; N is an integer greater than zero, and the preset length is greater than N times the GNSS precision.

Based on this possible implementation, the electronic device can determine the range of the large fence and the range of the small fence, so that by monitoring the position of the electronic device, it can be determined whether the electronic device reaches the range of the large fence or the range of the small fence.

With reference to the first aspect, in another possible implementation manner, the electronic device also establishes and stores the GNSS fences of other virtual cards except the first virtual card among the multiple virtual cards; wherein, the GNSS fences of other virtual cards include : the second GNSS fence corresponding to the second virtual card, the second GNSS fence includes a third fence and a fourth fence, and the range of the third fence is larger than the range of the fourth fence.

Based on this possible implementation, when the position of the monitoring electronic device reaches the range of the GNSS fence of other virtual cards, the virtual card corresponding to the GNSS geographic fence can be automatically activated, which avoids the user’s confusion when faced with different card swiping requirements. It is necessary to manually select the virtual card that needs to be activated, which can further simplify the process of swiping the card for the user, reduce the time for swiping the card, and improve the user experience.

With reference to the first aspect, in another possible implementation manner, when the electronic device monitors that the position of the electronic device reaches the range of the first GNSS fence, the electronic device activates the first virtual card, which may include: When the electronic device detects that the position of the electronic device is within the range of the first GNSS fence but not within the range of the GNSS fences of other virtual cards, the electronic device activates the first virtual card.

Based on this possible implementation, by judging whether the position of the electronic device is within the range of a GNSS fence, the accuracy of the virtual card activated by the electronic device can be improved.

With reference to the first aspect, in another possible implementation manner, when the electronic device monitors that the position of the electronic device reaches the range of the first GNSS fence, the electronic device activates the first virtual card, which may include: When the electronic device detects that the position of the electronic device is within the range of the second fence in the first GNSS fence and within the range of the third fence in the second GNSS fence, the electronic device activates the first virtual card.

Based on this possible implementation, by judging the priority of the fence, the virtual card corresponding to the small fence with high priority is activated, which avoids the need for the user to manually select the virtual card that needs to be activated when the position of the electronic device reaches the range of multiple fences. Card, so as to further simplify the process of users swiping cards, reduce the time for swiping cards, and improve user experience.

With reference to the first aspect, in another possible implementation manner, when the electronic device monitors that the position of the electronic device reaches the range of the first GNSS fence, the electronic device activates the first virtual card, which may include: The electronic device monitors that the position of the electronic device reaches the range of the first fence in the first GNSS fence, and reaches the range of the third fence in the second GNSS fence, or, monitors that the position of the electronic device reaches the first GNSS fence If it is within the range of the second fence in the second GNSS fence and within the range of the fourth fence of the second GNSS fence, the electronic device determines that the priority of the first virtual card is higher than the priority of the second virtual card; A virtual card is activated.

Based on this possible implementation, by further judging the priority of the virtual card, the virtual card with a higher priority is activated, which avoids that when the position of the electronic device reaches the range of multiple fences, and the priority of multiple fences is the same, The user manually selects the virtual card that needs to be activated, which further simplifies the process of swiping the card for the user, reduces the time for swiping the card, and improves the user experience.

With reference to the first aspect, in another possible implementation manner, the above virtual card switching method may further include: when the priority of the first virtual card is the same as that of the second virtual card, the electronic device obtains the electronic device The mobile trend; the electronic device will activate the virtual card corresponding to the GNSS fence on the mobile trend.

Based on this possible implementation, by activating the corresponding virtual card according to the mobile trend of the electronic device, it is avoided that when the position of the electronic device reaches within the range of multiple fences, the priority of multiple fences is the same, and the priority of the virtual card is also different. At the same time, the user manually selects the virtual card to be activated, which further simplifies the process of swiping the card for the user, reduces the time for swiping the card, and improves user experience.

With reference to the first aspect, in another possible implementation manner, the first virtual card is specifically a virtual card of a predetermined type among the plurality of virtual cards.

Based on this possible implementation, by using the first virtual card as a virtual card of a predetermined type among the plurality of virtual cards, it is possible for the electronic device to quickly determine whether to Build the fence corresponding to the virtual card.

With reference to the first aspect, in another possible implementation manner, the preset length is 1 kilometer; N is 5; or, the GNSS accuracy of N times is greater than 50 meters and less than 500 meters.

Based on this possible implementation, the electronic device can accurately determine the range of the large fence and the range of the small fence, so that by monitoring the position of the electronic device, it can be accurately determined whether the electronic device reaches the range of the large fence or the range of the small fence. within range.

In combination with the first aspect, in another possible implementation manner, the GNSS includes the global satellite positioning system GPS, the global navigation satellite system GLONASS, the Beidou satellite navigation system BDS, the quasi-zenith satellite system QZSS or the satellite-based augmentation system SBAS.

Based on this possible implementation, through GNSS including the global satellite positioning system GPS, the global navigation satellite system GLONASS, the Beidou satellite navigation system BDS, the quasi-zenith satellite system QZSS or the satellite-based augmentation system SBAS, the electronic device can establish a virtual card corresponding Different types of GNSS fences.

In a second aspect, an embodiment of the present application provides a virtual card switching device, which can be applied to an electronic device to implement the method in the first aspect above. The function of the virtual card switching device can be realized by hardware, and can also be realized by executing corresponding software by hardware. The hardware or software includes one or more modules corresponding to the above functions, for example, an acquisition module, an establishment module, a storage module, and an activation module.

Among them, the obtaining module can be used to obtain the GNSS position information and GNSS accuracy of the electronic device when the electronic device uses the first virtual card to complete data interaction at the first card swiping point for the first time; the first virtual card is multiple A virtual card in a virtual card. The establishment module can be used to establish the first GNSS fence corresponding to the first virtual card according to the GNSS position information and the GNSS accuracy. The first GNSS fence includes the first fence and the second fence, and the range of the first fence is larger than that of the second fence. scope. The storage module can be used to store the first GNSS fence corresponding to the first virtual card. The activation module may be configured to activate the first virtual card when the electronic device monitors that the position of the electronic device is within the range of the first GNSS fence.

In conjunction with the second aspect, in another possible implementation, the first fence is a circular area with the GNSS position information as the center and the preset length as the radius; the second fence is the GNSS position information as the center, with N times the GNSS precision is a circular area with a radius; N is an integer greater than zero, and the preset length is greater than N times the GNSS precision.

In conjunction with the second aspect, in another possible implementation, the establishment module can also be used to establish the GNSS fences of other virtual cards except the first virtual card among the multiple virtual cards; wherein, the GNSS fences of other virtual cards It includes: a second GNSS fence corresponding to the second virtual card, the second GNSS fence includes a third fence and a fourth fence, and the range of the third fence is larger than the range of the fourth fence. The storage module can also be used to store the GNSS fences of other virtual cards in the plurality of virtual cards except the first virtual card.

With reference to the second aspect, in another possible implementation manner, the activation module is specifically configured to detect that the position of the electronic device reaches within the range of the first GNSS fence and does not reach the range of the GNSS fence of other virtual cards. Within the case, the first virtual card will be activated.

With reference to the second aspect, in another possible implementation manner, the activation module is specifically configured to, when the electronic device detects that the position of the electronic device reaches within the range of the second fence in the first GNSS fence, and reaches the second GNSS fence In case of being within range of the third fence, the first virtual card will be activated.

With reference to the second aspect, in another possible implementation manner, the above virtual card switching device may further include: a determining module. The determination module can be used to detect that the position of the electronic device reaches within the range of the first fence in the first GNSS fence and reaches the range of the third fence in the second GNSS fence, or monitors that When the position of the electronic device reaches within the range of the second fence in the first GNSS fence and reaches within the range of the fourth fence of the second GNSS fence, determine the first virtual card The priority of the second virtual card is higher than that of the second virtual card. The activation module is specifically configured to activate the first virtual card.

With reference to the second aspect, in another possible implementation manner, the acquiring module is further configured to acquire a movement trend of the electronic device. The activation module is also used to activate the virtual card corresponding to the GNSS fence on the mobile trend.

With reference to the second aspect, in another possible implementation manner, the preset length is 1 kilometer; N is 5; or, the GNSS accuracy of N times is greater than 50 meters and less than 500 meters.

With reference to the second aspect, in another possible implementation manner, the GNSS includes the global satellite positioning system GPS, the global navigation satellite system GLONASS, the Beidou satellite navigation system BDS, the quasi-zenith satellite system QZSS or the satellite-based augmentation system SBAS.

In a third aspect, an embodiment of the present application provides an electronic device, including: a processor, and a memory configured to store instructions executable by the processor. When the processor is configured to execute the above instructions, the electronic device implements the virtual card switching method described in any one of the first aspect or possible implementation manners of the first aspect.

In a fourth aspect, the embodiment of the present application provides a computer-readable storage medium on which computer program instructions are stored. When the computer program instructions are executed by the electronic device, the electronic device is made to implement the virtual card switching method described in any one of the first aspect or possible implementation manners of the first aspect.

In the fifth aspect, the embodiment of the present application provides a computer program product, including computer readable code, when the computer readable code is run in the electronic device, the electronic device realizes the possible functions of the first aspect or the first aspect. Implement the virtual card switching method described in any one of the manners.

It should be understood that, for the beneficial effects of the above-mentioned second aspect to the fifth aspect, reference may be made to relevant descriptions in the above-mentioned first aspect, and details are not repeated here.

Description of drawings

Fig. 1 is a schematic diagram of the application scenario of the NFC virtual card provided by the embodiment of the present application;

FIG. 2 is a schematic diagram of a display interface of an electronic device provided in an embodiment of the present application;

FIG. 3 is a schematic structural diagram of an electronic device provided in an embodiment of the present application;

FIG. 4 is a first schematic diagram of the framework of the virtual card switching method provided by the embodiment of the present application;

FIG. 5 is a second schematic diagram of the framework of the virtual card switching method provided by the embodiment of the present application;

FIG. 6 is a schematic diagram of a method for establishing a geographic fence corresponding to a virtual card provided in an embodiment of the present application;

FIG. 7 is a first schematic diagram of a geo-fence provided by an embodiment of the present application;

FIG. 8 is a second schematic diagram of the geofence provided by the embodiment of the present application;

FIG. 9 is a first schematic diagram of a virtual card switching method provided by an embodiment of the present application;

FIG. 10 is a schematic diagram of virtual card switching provided by the embodiment of the present application;

FIG. 11 is a second schematic diagram of a virtual card switching method provided by the embodiment of the present application;

FIG. 12 is a schematic structural diagram of a virtual card switching device provided by an embodiment of the present application.

Detailed ways

The following will clearly and completely describe the technical solutions in the embodiments of the application with reference to the drawings in the embodiments of the application. Apparently, the described embodiments are only some of the embodiments of the application, not all of them. Based on the embodiments in this application, all other embodiments obtained by persons of ordinary skill in the art without making creative efforts belong to the scope of protection of this application.

The terms "first" and "second" are used for descriptive purposes only, and cannot be understood as indicating or implying relative importance or implicitly specifying the quantity of indicated technical features. Thus, a feature defined as "first" and "second" may explicitly or implicitly include one or more of these features. In the description of the present application, unless otherwise specified, "plurality" means two or more.

At present, NFC technology has been gradually extended to miniaturized electronic devices. Electronic devices that support NFC functions, such as mobile phones, can exchange data with NFC card readers when they are close to NFC card readers (such as point of sale (POS) machines), thereby realizing various NFC card readers. Functions, such as card swiping, data transfer, etc. For example, as shown in Figure 1, mobile phone 101 has NFC function, and the user can put mobile phone 101 close to the NFC card reader 102 on the bus when taking a bus, so that mobile phone 101 can communicate with the NFC card reader 102 on the bus. Perform data exchange, that is, the mobile phone 101 completes the payment of the bus fare.

Generally, an electronic device supporting the NFC function may include an application program (for example, called an NFC application) for implementing short-distance communication. The NFC application has an emulation function of emulating a contactless integrated circuit (integrated circuit, IC) card. For example, NFC applications may include card package applications, bus applications, banking applications, access control applications, and the like.

Each NFC application includes at least one virtual card, such as a virtual transportation card, a virtual access control card, and a virtual bank card. Each virtual card may correspond to an identifier, and the identifier may be an application identifier (applet identifier, AID) or an identifier (identity, ID). When the virtual card supports AID identification, the virtual card can be identified by the AID. And some virtual cards do not support AID identification, such as Mifare series cards, such as residential access control cards, can be identified by ID. The mapping relationship between the virtual card and the identification of the NFC application can be stored in the memory of the electronic device, and can also be stored in the cloud. As an example, assume that the above mapping relationship is stored in the memory of the electronic device, and the NFC application is a card package application as an example. Table 1 shows the mapping relationship between the virtual card and the identifier of the card package application stored in the memory of the electronic device.

Table 1

According to Table 1, in the electronic device, the card package application may include multiple virtual cards of different types, such as community access control cards, public transportation cards and smart door lock cards. At the same time, the activation status of one of the multiple virtual cards is activated, for example, the activation status of the smart door lock card identified as AID2 is activated.

When the electronic device receives the NFC field strength information (that is, the electronic device is close to an NFC card reader), the electronic device defaults to the activated virtual card for data interaction with the nearby NFC card reader (that is, completes the transaction). On the activated virtual card, often the pre-configured default card. When the NFC card reader matches the default card, the data exchange between the NFC card reader and the electronic device can be successful. However, when the NFC card reader does not match the default card, data interaction failure will occur. When the NFC card reader does not match the default card, the user needs to manually select the correct virtual card to achieve successful interaction with the NFC card reader.

For example, take the electronic device as a mobile phone as an example. As shown in (a) in FIG. 2 , the default card in the card package application of the mobile phone is a smart door lock card, that is, the virtual card in an activated state is a smart door lock card. When the mobile phone is close to the NFC card reader of the bus, the mobile phone can receive instruction information including the identification (eg, AID1). After that, the mobile phone can use the default card to exchange data with the NFC card reader on the bus. If the user starts the card package application of the mobile phone at this time, the mobile phone can display the card swiping interface 201 shown in (b) in FIG. Data interaction. Of course, it is also possible that the screen of the mobile phone is turned on in response to the received instruction information, and displays the interface of the card package application, for example, the above-mentioned card swiping interface 201 is displayed. In addition, the mobile phone can also compare whether the identifier (ie, AID1) in the indication information is the same as that of the default card (ie, AID2). When the mobile phone determines that the two are different, it can display the card swiping interface 202 as shown in (c) in FIG. Afterwards, the user can manually select the correct virtual card to activate. For example, the mobile phone receives the user's selection operation on the public transportation card, and in response, the smart door lock card that is currently activated can be deactivated and the public transportation card can be activated. After that, when the mobile phone is close to the NFC card reader on the bus again, use the activated public transportation card to interact with the NFC card reader on the bus to perform operations such as deduction of the amount, and notify the NFC card reader on the bus to finish swiping the card. Generally, after swiping the card, the mobile phone can also deactivate the public transportation card and reactivate the default card (ie, the smart door lock card).

It can be seen from this that when the NFC card reader does not match the currently activated virtual card, such as the default card, that is, when faced with different card swiping requirements, the user needs to manually select the correct virtual card to activate in order to complete the activation with the NFC card reader. data interaction. Like this, cause comparatively loaded down with trivial details of the card swiping process, the time is longer.

In related technologies, a wireless fidelity (Wi-Fi) geo-fence is used to realize the automatic activation of the corresponding virtual card before the user swipes the card.

Geo-fence means that when the user arrives near a certain geographical location, the user's mobile phone can monitor the longitude and latitude coordinates of the mobile phone, the logo of the cell base station scanned by the mobile phone, or the Wi-Fi information (such as Wi-Fi ID), and match with the location information corresponding to the geographic location, the ID of the cell (Cell) base station or Wi-Fi information, and after the matching is successful, the mobile phone can determine that the user enters the geofence corresponding to the geographic location.

Geofences can be divided into GNSS (global navigation satellite system, GNSS) geofences, Cell geofences, and Wi-Fi geofences according to their monitoring data.

The GNSS geographic fence monitoring dimension can be the latitude and longitude coordinates of the mobile phone. The monitoring area of the GNSS geo-fence can be a circular area with a certain geographic location coordinate point as the center and a certain length as the radius, or a polygonal area with multiple geographic location coordinate points as vertices and connected vertices.

The monitoring dimension of the Cell geo-fence may be the identification of the base station of the cell scanned by the mobile phone. The monitoring area of the Cell geo-fence may be the signal coverage of one or more cell base stations.

The monitoring dimension of the Wi-Fi geofence can be the Wi-Fi signal scanned by the mobile phone. The monitoring area of the Wi-Fi geo-fence can be covered by one or more Wi-Fi signals.

After the mobile phone determines that the user enters the geographic fence corresponding to the geographic location, the fence mechanism corresponding to the geographic location can be triggered to perform operations corresponding to the fence corresponding to the geographic location, for example, the card corresponding to the geographic location can be activated.

Specifically, the solution of the above-mentioned related technology is: when a user uses a virtual card to conduct a transaction, the mobile phone sets a Wi-Fi geo-fence according to the identity of the virtual card and the Wi-Fi identity corresponding to the location where the user swipes the card, and saves the Wi-Fi - Correspondence between the Wi-Fi ID in the Fi geofence and the virtual card ID. After that, the mobile phone can periodically obtain the Wi-Fi identification of the current geographical location of the mobile phone, and judge whether the obtained Wi-Fi identification is the same as the Wi-Fi identification in the set W-iFi geo-fence. When the mobile phone detects that the obtained Wi-Fi identifier is the same as the Wi-Fi identifier in the Wi-Fi geo-fence, it is determined that the user has entered the Wi-Fi geo-fence. At this time, the mobile phone can automatically activate the virtual card corresponding to the Wi-Fi geo-fence according to the saved correspondence, so that the user can use the activated virtual card to complete card swiping. That is, the automatic activation of the corresponding virtual card is realized before the user swipes the card.

However, the implementation of the above solution requires the mobile phone to have the capability of Wi-Fi geo-fencing, for example, the sensor hub (sensorhub) in the mobile phone is required to have the capability of low-power Wi-Fi geo-fencing. When the mobile phone does not have the Wi-Fi geo-fence capability, the setting of the virtual card corresponding to the Wi-Fi geo-fence cannot be realized, and the corresponding virtual card cannot be automatically activated before the user swipes the card. In this way, the user still needs to manually select the correct virtual card for activation.

In view of the above problems, the embodiment of the present application provides a virtual card switching method, which should be applied to electronic devices. This method can be used according to the current GNSS position information of the electronic device when the user completes the transaction with a certain virtual card at a certain card swiping point for the first time. Establish the GNSS geofence corresponding to the virtual card. Afterwards, when the user enters the GNSS geofence again with the electronic device, the electronic device can automatically activate the virtual card corresponding to the GNSS geofence, so that the user can use the virtual card to complete transactions. That is, before the user swipes the card, the electronic device can automatically activate the corresponding virtual card by using the GNSS geo-fence.

In this way, when faced with different card swiping requirements, the user can avoid the need to manually select a virtual card, thereby reducing the time for swiping a card and improving user experience. Moreover, the solution of the present application is to establish a corresponding geographic fence based on the GNSS position information, and the GNSS position information can be obtained by using the short-distance chip of the electronic device. The short-distance chip is a standard configuration of electronic equipment, so even if the electronic equipment does not have the Wi-Fi fence capability, it can still realize the automatic activation of the corresponding virtual card before the user swipes the card, further improving the user experience.

It can be understood that GNSS can include global positioning system (global positioning system, GPS), global navigation satellite system (global navigation satellite system, GLONASS), Beidou satellite navigation system (beidou navigation satellite system, BDS), quasi-zenith satellite system (quasi-zenith satellite system, QZSS) and/or satellite based augmentation systems (satellite based augmentation systems, SBAS), etc. Therefore, the GNSS geo-fence in this embodiment may be a GPS geo-fence, a GLONASS geo-fence, a Beidou geo-fence, a QZSS geo-fence, or an SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the following embodiments of the present application, a GNSS geo-fence is taken as a GPS geo-fence (hereinafter referred to as a GPS geo-fence) as an example for schematic illustration. That is, the monitoring dimension of the GPS fence may be the latitude and longitude coordinates of the electronic device. The monitoring area of the GPS fence can be a circular area with a certain geographic location coordinate point as the center and a certain length as the radius, or a polygonal area with multiple geographic location coordinate points as vertices and connected vertices.

In addition, in some examples, the above-mentioned electronic devices may be mobile phones, tablet computers, handheld computers, personal computers (personal computers, PCs), cellular phones, personal digital assistants (personal digital assistants, PDAs), wearable devices, etc. functional electronic devices. The embodiment of the present application does not limit the specific form of the electronic device.

Exemplarily, taking the electronic device as a mobile phone as an example, FIG. 3 shows a schematic structural diagram of an electronic device provided by an embodiment of the present application.

As shown in Figure 3, the electronic device may include a processor 310, an external memory interface 320, an internal memory 321, a universal serial bus (universal serial bus, USB) interface 330, a charging management module 340, a power management module 341, a battery 342, Antenna 1, antenna 2, mobile communication module 350, wireless communication module 360, audio module 370, speaker 370A, receiver 370B, microphone 370C, earphone jack 370D, sensor module 380, button 390, motor 391, indicator 392, camera 393, A display screen 394, and a subscriber identification module (subscriber identification module, SIM) card interface 395, etc. Among them, the sensor module 380 may include a pressure sensor 380A, a gyroscope sensor 380B, an air pressure sensor 380C, a magnetic sensor 380D, an acceleration sensor 380E, a distance sensor 380F, a proximity light sensor 380G, a fingerprint sensor 380H, a temperature sensor 380J, a touch sensor 380K, an environment Light sensor 380L, bone conduction sensor 380M, etc.

It should be understood that the structure shown in this embodiment does not constitute a specific limitation on the electronic device. In other embodiments, the electronic device may include more or fewer components than shown, or combine certain components, or separate certain components, or arrange different components. The illustrated components can be realized in hardware, software or a combination of software and hardware.

The processor 310 may include one or more processing units, for example: the processor 310 may include an application processor (application processor, AP), a modem processor, a graphics processing unit (graphics processing unit, GPU), an image signal processor (image signal processor, ISP), controller, memory, video codec, digital signal processor (digital signal processor, DSP), baseband processor, and/or neural network processor (neural-network processing unit, NPU) Wait. Wherein, different processing units may be independent devices, or may be integrated in one or more processors.

In the embodiment of the present application, the processor 310 may further include a sensor hub (sensorhub) and a short-distance processor (also referred to as a short-distance chip). The short-range chip can be used to obtain GPS positioning information and Wi-Fi scanning information. In some embodiments, the short-range chip may include two chips, namely a GPS chip and a Wi-Fi chip, the GPS chip is used to obtain GPS positioning information, and the Wi-Fi chip is used to obtain Wi-Fi scanning information.

A controller can be the nerve center and command center of an electronic device. The controller can generate an operation control signal according to the instruction opcode and timing signal, and complete the control of fetching and executing the instruction.

A memory may also be provided in the processor 310 for storing instructions and data. In some embodiments, the memory in processor 310 is a cache memory. The memory may hold instructions or data that the processor 310 has just used or recycled. If the processor 310 needs to use the instruction or data again, it can be called directly from the memory. Repeated access is avoided, and the waiting time of the processor 310 is reduced, thereby improving the efficiency of the system.

In some embodiments, processor 310 may include one or more interfaces. The interface may include an integrated circuit (inter-integrated circuit, I2C) interface, an integrated circuit built-in audio (inter-integrated circuit sound, I2S) interface, a pulse code modulation (pulse code modulation, PCM) interface, a universal asynchronous transmitter (universal asynchronous receiver/transmitter, UART) interface, mobile industry processor interface (mobile industry processor interface, MIPI), general-purpose input and output (general-purpose input/output, GPIO) interface, subscriber identity module (subscriber identity module, SIM) interface, and /or universal serial bus (universal serial bus, USB) interface, etc.

The wireless communication function of the electronic device can be realized by the antenna 1, the antenna 2, the mobile communication module 350, the wireless communication module 360, the modem processor and the baseband processor.

Antenna 1 and Antenna 2 are used to transmit and receive electromagnetic wave signals. Each antenna in an electronic device can be used to cover a single or multiple communication frequency bands. Different antennas can also be multiplexed to improve the utilization of the antennas. For example: Antenna 1 can be multiplexed as a diversity antenna of a wireless local area network. In other embodiments, the antenna may be used in conjunction with a tuning switch.

The mobile communication module 350 can provide wireless communication solutions including 2G/3G/4G/5G applied to electronic devices. The mobile communication module 350 may include at least one filter, switch, power amplifier, low noise amplifier (low noise amplifier, LNA) and the like. The mobile communication module 350 can receive electromagnetic waves through the antenna 1, filter and amplify the received electromagnetic waves, and send them to the modem processor for demodulation. The mobile communication module 350 can also amplify the signal modulated by the modem processor, convert it into electromagnetic wave and radiate it through the antenna 1 . In some embodiments, at least part of the functional modules of the mobile communication module 350 may be set in the processor 310 . In some embodiments, at least part of the functional modules of the mobile communication module 350 and at least part of the modules of the processor 310 may be set in the same device.

The wireless communication module 360 can provide wireless local area networks (wireless local area networks, WLAN) (such as wireless fidelity (Wi-Fi) network), bluetooth (bluetooth, BT), global navigation satellite system, etc. (global navigation satellite system, GNSS), frequency modulation (frequency modulation, FM), near field communication technology (near field communication, NFC), infrared technology (infrared, IR) and other wireless communication solutions. The wireless communication module 360 may be one or more devices integrating at least one communication processing module. The wireless communication module 360 receives electromagnetic waves via the antenna 2 , frequency-modulates and filters the electromagnetic wave signals, and sends the processed signals to the processor 310 . The wireless communication module 360 can also receive the signal to be sent from the processor 310 , frequency-modulate it, amplify it, and convert it into electromagnetic waves through the antenna 2 for radiation.

In some embodiments, the antenna 1 of the electronic device is coupled to the mobile communication module 350, and the antenna 2 is coupled to the wireless communication module 360, so that the electronic device can communicate with the network and other devices through wireless communication technology. The wireless communication technology may include global system for mobile communications (GSM), general packet radio service (general packet radio service, GPRS), code division multiple access (code division multiple access, CDMA), broadband Code division multiple access (wideband code division multiple access, WCDMA), time division code division multiple access (time-division code division multiple access, TD-SCDMA), long term evolution (long term evolution, LTE), BT, GNSS, WLAN, NFC , FM, and/or IR techniques, etc.

The electronic device realizes the display function through the GPU, the display screen 394 , and the application processor. GPU is a microprocessor for image processing, connected to display screen 394 and application processor. GPUs are used to perform mathematical and geometric calculations for graphics rendering. Processor 310 may include one or more GPUs that execute program instructions to generate or alter display information.

The display screen 394 is used to display images, videos and the like. Display 394 includes a display panel. The display panel can be a liquid crystal display (LCD), an organic light-emitting diode (OLED), an active matrix organic light emitting diode or an active matrix organic light emitting diode (active-matrix organic light emitting diode, AMOLED), flexible light-emitting diode (flex light-emitting diode, FLED), Miniled, MicroLed, Micro-oLed, quantum dot light emitting diodes (quantum dot light emitting diodes, QLED), etc. In some embodiments, the electronic device may include 1 or N display screens 394, where N is a positive integer greater than 1.

In the embodiment of the present application, the display screen 394 may be used to display the interface of the electronic device.

The electronic device can realize the shooting function through ISP, camera 393 , video codec, GPU, display screen 394 and application processor. In some embodiments, the electronic device may include 1 or N cameras 393, where N is a positive integer greater than 1.

The internal memory 321 may be used to store computer-executable program code, which includes instructions. The processor 310 executes various functional applications and data processing of the electronic device by executing instructions stored in the internal memory 321 . The internal memory 321 may include an area for storing programs and an area for storing data. Wherein, the stored program area can store an operating system, at least one application program required by a function (such as a sound playing function, an image playing function, etc.) and the like. The storage data area can store data (such as audio data, phone book, etc.) created during the use of the electronic device. In addition, the internal memory 321 may include a high-speed random access memory, and may also include a non-volatile memory, such as at least one magnetic disk storage device, flash memory device, universal flash storage (universal flash storage, UFS) and the like.

The acceleration sensor 380E can periodically collect acceleration data of the electronic device according to a certain frequency. For example, the acceleration of the electronic device in various directions (generally XYZ three-axis directions) can be collected.

Of course, it can be understood that what is shown in FIG. 3 above is only an exemplary description when the form of the electronic device is a mobile phone. If the electronic device is a tablet computer, handheld computer, PC, PDA, wearable device (such as: smart watch, smart bracelet) and other device forms, the structure of the electronic device may include fewer components than those shown in Figure 3. The structures may also include more structures than those shown in FIG. 3 , which is not limited here.

It can be understood that, generally speaking, the realization of the functions of electronic equipment requires not only the support of hardware, but also the cooperation of software.

For example, in some examples of the present application, as shown in Figure 4, to realize the automatic switching of the virtual card of the electronic device, at least a processor, such as a sensorhub, a short-distance chip, and a baseband processor (also called a baseband chip) and other hardware are required It also requires the cooperation of applications using fences, such as NFC card package applications (such as smart flash card applications) and applications in system services (such as GPS applications, Wi-Fi applications). The software and hardware can be connected through the hardware connection layer.

Wherein, as shown in Figure 4, taking the application in the system service as a GPS application, and the geofence established by the electronic device as a GPS fence as an example, the process for the electronic device to automatically switch virtual cards may include: When a virtual card is used for the first time to complete a transaction, the short-range chip obtains GPS location information. The short-distance chip sends GPS positioning information to the smart flash card application through the sensorhub, hardware connection layer and GPS application. The smart flash card application builds a GPS fence, and sends the built GPS fence to the GPS application. The GPS application stores and manages the fence established by the smart flash card application. . The GPS application sends the established GPS fence to sensorhub. After that, the sensorhub can periodically obtain the GPS positioning information of the electronic device from the short-range chip. The sensorhub can include fence algorithms, such as GPS fence algorithms, cell fence algorithms, and Wi-Fi fence algorithms. The sensorhub obtains GPS location information from the short-distance chip, and uses the built-in fence algorithm, such as the GPS fence algorithm to determine whether the user enters the GPS fence. The sensorhub does not need to wake up the main processor of the electronic device when it is working, thereby achieving low-power fence capabilities. When sensorhub determines that the user enters the GPS fence, sensorhub sends the GPS fence that the user entered to the smart card application through the GPS application, so that the smart card activates the virtual card corresponding to the GPS fence according to the GPS fence that the user enters.

The above example is illustrated by taking the processor of the electronic device including a sensorhub and the short-range chip as an example, that is, the short-range chip can be used to obtain GPS positioning information, and can also be used to obtain Wi-Fi scanning information. In another embodiment, the processor of the electronic device may not include a sensorhub, and the short-distance chip may include two chips, namely a GPS chip and a Wi-Fi chip, the GPS chip is used to obtain GPS positioning information, and the Wi-Fi The chip is used to obtain Wi-Fi scanning information, as shown in Figure 5, continue to take the application in the system service as the GPS application, and the fence established by the electronic device as the GPS fence as an example, the process of the electronic device to realize the automatic switching of the virtual card can be Including: when a user completes a transaction with a virtual card at a certain card swiping point for the first time, the GPS chip obtains GPS positioning information. The GPS chip sends the GPS positioning information to the smart flash card application through the hardware connection layer and the GPS application. The smart flash card application builds a GPS fence and sends the built GPS fence to the GPS application. The GPS application stores and manages the fence established by the smart flash card application. The GPS application sends the established GPS fence to the GPS chip. Afterwards, the GPS chip can periodically obtain GPS positioning information, and use its included GPS fence algorithm to determine whether the user enters the GPS fence. When it is determined that the user enters the GPS fence, the GPS chip sends the GPS fence that the user entered to the smart flash card application through the GPS application. The GPS chip can work independently without waking up the main processor of the electronic device, thereby realizing low-power fence capability . According to the GPS fence that the user enters, the smart flash card activates the virtual card corresponding to the GPS fence.

The virtual card switching method provided by the embodiment of the present application will be described in detail below with reference to FIG. 4 . Wherein, in this embodiment, the method may include: a "fence establishment" process and a "virtual card switching" process.

As shown in Fig. 6, the "fence establishment" process may include the following S601-S605.

S601. The smart flash card application of the electronic device acquires a first virtual card.

When using the virtual card on the electronic device, the user can open the virtual card on the electronic device, such as the smart flash card application of the electronic device. For example, the user may click on the option to activate immediately in the smart flash card application of the electronic device. In response to the user's click operation, the electronic device displays virtual card options that can be activated, such as public transportation card options. After that, the user can select the public transportation card and select the corresponding activation area. In response to the user's selection operation, the electronic device successfully opens a public transportation card.

After the virtual card is opened on the electronic device, the electronic device, such as the smart flash card application of the electronic device, can obtain the first virtual card, and the first virtual card can be the virtual card opened by the electronic device.

Electronic devices with NFC functions can include multiple virtual cards, such as community access cards, public transportation cards, smart door lock cards, and corresponding virtual cards for luggage, car keys, and ID cards, so as to meet different card swiping needs.

For the virtual cards in the electronic device, when the user uses any virtual card to conduct transactions, the electronic device can establish a corresponding geographic fence. A card virtual card can establish one geo-fence or multiple geo-fences. For example, when the user uses a public transportation card to swipe the card at bus stop A, the electronic device may establish a geographic fence corresponding to the public transportation card at bus stop A. When the user uses the public transportation card to swipe the card at the bus station B, the electronic device can establish a geographic fence corresponding to the public transportation card at the bus station B.

In some embodiments, when the electronic device has many geo-fences corresponding to the subsequently established virtual card, the electronic device can delete some of the geo-fences according to the actual situation, such as the geo-fences that have not been used within a preset period of time, Electronic devices can remove this geofence. For example, an electronic device, such as the smart flash card application of an electronic device, can determine whether the established geo-fence has reached the corresponding validity period. The validity period can be set according to the actual situation. When the geo-fence reaches the corresponding validity period, the electronic device, such as the The smart flash card application can delete the geofence.

Among the above-mentioned virtual cards, some of the virtual cards have fixed card swiping points, and this kind of virtual card is called the first virtual card of a predetermined type in this embodiment, such as car keys, community access cards, public transportation cards, and smart door lock cards, etc. , and the corresponding card swiping points are generally fixed. However, the swiping points of some virtual cards are indeed not fixed, such as the corresponding virtual cards such as bags and ID cards. The swiping points of these virtual cards may change with different places of use.

In some embodiments, since the geo-fence needs to be established at a fixed location, a corresponding geo-fence may be established for a virtual card with a fixed swiping point, that is, the first virtual card of a predetermined type. As for the virtual card whose card swiping point is not fixed, the electronic device cannot establish a geographic fence corresponding to the virtual card because the card swiping point is not fixed. Therefore, before the electronic device establishes the geographic fence corresponding to the virtual card, the electronic device, such as the smart flash card application of the electronic device, can first determine the virtual card with a fixed swiping point according to whether the swiping point of the virtual card is fixed, that is, the first type of the predetermined type. A virtual card, so that when the electronic device uses a certain first virtual card to complete a transaction at a certain card swiping point for the first time, it can establish a geo-fence corresponding to the first virtual card.

In some examples, the electronic device may determine whether the virtual card is a first virtual card of a predetermined type according to the type of the virtual card. For example, if the swipe point of the community access control card is a community, the location of the swipe point is fixed, so when the type of the virtual card is a community access card, the electronic device can determine that the swipe point of the virtual card is fixed, that is, the community access card is a first virtual card of a predetermined type. The virtual card swiping point corresponding to the car key is the parking position of the vehicle. If the parking position of the vehicle is fixed every day, that is, the user uses the virtual card corresponding to the car key to open the vehicle at the same location every day, the position of the swiping point is Therefore, when the type of the virtual card is the virtual card corresponding to the car key, the electronic device can determine that the card swiping point of the virtual card is fixed, that is, the virtual card corresponding to the car key is the first virtual card of a predetermined type.

The card swiping point of the virtual card corresponding to the ID card can be a bank, a company, or a home, that is, the position of the card swiping point of the virtual card corresponding to the ID card is not fixed. When the virtual card is selected, the electronic device may determine that the virtual card is not the first virtual card.

In some embodiments, after the electronic device determines the first virtual card, the electronic device, such as the smart flash card application in the electronic device, may save the identifier (such as AID) of the first virtual card in a corresponding list.

For example, as shown in FIG. 4 , the smart flash card application of the electronic device can determine the virtual card with a fixed swiping point, that is, the first virtual card of a predetermined type, and store the identifier corresponding to the first virtual card in the smart flash card list middle. Afterwards, the electronic device, such as the smart flash card application of the electronic device, can determine whether to subsequently establish a geofence corresponding to the first virtual card according to the list. For example, when a user uses a first virtual card in the smart flash card list to complete a transaction at a certain card swiping point for the first time, the smart flash card application of the electronic device may establish a geo-fence corresponding to the first virtual card. When the user completes the transaction with a virtual card in the list of non-smart flash cards, the smart flash card application of the electronic device does not need to establish a geo-fence.

Wherein, the process of establishing a geographic fence by the smart card application of the electronic device may include the following S602-S605.

S602. The smart flash card application of the electronic device obtains the current geographic location information and geographic location accuracy of the electronic device when a certain first virtual card is used to complete data interaction with the NFC card reader at a certain card swiping point for the first time.

When the user uses the above-mentioned first virtual card to complete the transaction at a certain card-swiping point (such as the first card-swiping point) for the first time, that is, when the first virtual card is used to complete the data interaction with the NFC card reader corresponding to a certain card-swiping point, the electronic The device, such as the smart flash card application of the electronic device, can establish a geographic fence corresponding to the first virtual card.

The geo-fence corresponding to the first virtual card may be at least one of a GNSS geo-fence, a Cell geo-fence, or a Wi-Fi geo-fence. The GNSS geo-fence may include GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence, etc.

The specific type of the GNSS geo-fence is not limited in this application. For ease of understanding, in this embodiment of the application, the geographic fence corresponding to the first virtual card is an example of a GNSS geographic fence for schematic illustration. The GNSS geographic fence corresponding to the first virtual card can be the first GNSS fence in the embodiment of this application .

Because GNSS geo-fences include GPS geo-fences, GLONASS geo-fences, Beidou geo-fences, QZSS geo-fences or SBAS geo-fences, etc. The specific type of the GNSS geo-fence is not limited in this application. For ease of understanding, in the following embodiments of the present application, a GNSS geo-fence is taken as a GPS geo-fence (hereinafter referred to as a GPS geo-fence) as an example for schematic illustration. That is, the current geographic location information of the electronic device in this application may be GPS location information, and the geographic location accuracy may be GPS accuracy.

When the electronic device uses the first virtual card to complete the data interaction with the NFC card reader corresponding to a certain card swiping point, the electronic device, such as the smart flash card application of the electronic device, can obtain the current GPS location information and GPS accuracy of the electronic device, so that A GPS fence corresponding to the first virtual card is established according to the current GPS location information and GPS accuracy of the electronic device.

Among them, the electronic device, such as the smart flash card application of the electronic device, can determine whether the user at a certain card swiping point manually selects a certain first virtual card from a plurality of first virtual cards to complete the transaction. The first virtual card is used to complete the transaction for the first time.

It can be understood that the electronic device may include multiple first virtual cards. When the user swipes the card for the first time at a certain card swiping point, the user can manually select the first virtual card to be used from the multiple first virtual cards, so that the electronic device can The transaction is completed using the first virtual card selected by the user. That is, when the user manually selects the first virtual card that needs to be used from multiple first virtual cards to complete the transaction, the electronic device, such as the smart flash card application of the electronic device, can determine that the first virtual card is used for the first time at the card swiping point to complete the transaction. trade. For example, as shown in (c) in FIG. 2 , the first virtual card in the mobile phone includes a smart door lock card, a community access control card, and a public transportation card. When a user takes a bus at a certain bus station for the first time, the user can manually choose to use the public transportation card to complete the transaction among the community access control card, public transportation card and smart door lock card, that is, the mobile phone can determine that the user uses the public transportation card for the first time at the bus station. The public transport card completes the transaction.

When a user uses an electronic device to complete a transaction with a first virtual card at a certain card swiping point for the first time, that is, when the first virtual card completes data interaction with the NFC card reader, the electronic device, such as the smart flash card application in the electronic device, can The current GPS location information of the electronic device, such as latitude and longitude coordinates, and GPS accuracy (accuracy, acc) are obtained. When the user moves with the electronic device, the GPS location information of the electronic device is the GPS location information of the user.

GPS accuracy, defined as the radius with 68% confidence. That is to say, with the latitude and longitude coordinates obtained by the electronic device as the center and the precision acc as the radius of a circle, the probability that the current real position of the electronic device is located in the circle is 68%.

For example, in conjunction with the example in Figure 4, at a certain card swiping point, the smart flash card application of the electronic device determines that the user manually selects a first virtual card from multiple first virtual cards to complete the transaction, and the smart flash card application can pass Applications in system services (such as GPS applications), hardware connection layer and sensorhub obtain GPS location information and GPS accuracy from short-distance chips. Specifically, the above S602 may specifically include the following S6021-S6028.

S6021. The smart flash card application determines that a certain first virtual card is used to complete data interaction with the NFC card reader at a certain card swiping point for the first time.

S6022. The smart flash card application sends an acquisition notification to the GPS application.

The acquisition notification is used to instruct the GPS application to acquire the current GPS location information and GPS accuracy of the electronic device.

S6023. The GPS application sends an acquisition notification to the sensor hub.

After the GPS application receives the acquisition notification, it can send the acquisition notification to the sensorhub through the hardware connection layer.

S6024. The sensor hub sends an acquisition notification to the short-distance chip.

After sensorhub receives the acquisition notification, it can send the acquisition notification to the short-distance chip.

S6025. The short-distance chip sends the current GPS position information and GPS accuracy of the electronic device to the sensor hub.

S6026. The sensor hub sends the current GPS location information and GPS accuracy of the electronic device to the GPS application.

After sensorhub receives the current GPS location information and GPS accuracy of the electronic device, it can send the current GPS location information and GPS accuracy of the electronic device to the GPS application through the hardware connection layer.

S6027. The GPS application sends the current GPS location information and GPS accuracy of the electronic device to the smart flash card application.

S6028. The smart flash card application receives current GPS location information and GPS accuracy of the electronic device.

S603. The smart flash card application of the electronic device establishes a geo-fence corresponding to the first virtual card according to the geographic location information and the geographic location accuracy.

The geo-fence corresponding to the first virtual card may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the following embodiments of the present application, the geographical fence corresponding to the first virtual card is taken as an example for schematic illustration. When the geographic fence is a GPS fence, the geographic location information is the GPS location information, and the geographic location accuracy is the GPS accuracy.

The GPS fence can be a circular area with the acquired GPS location information as the center and a preset length as the radius. For example, as shown in Figure 4, after the electronic device, such as the smart card application of the electronic device, obtains the GPS location information and GPS accuracy, the smart card application can establish a center centered on the GPS location information and a preset length as the radius. A GPS fence corresponding to the first virtual card.

It can be understood that when the radius of the GPS fence is too large, overlapping areas tend to exist among different GPS fences. However, when the user enters the overlapping area with the electronic device, the electronic device cannot determine which virtual card corresponding to the GPS fence will be activated. When the radius of the GPS fence is too small, the real location of the user when swiping the card may be outside the GPS fence, so that the electronic device cannot automatically select the correct virtual card and activate it before the user swipes the card.

Therefore, in some embodiments of the present application, the electronic device, such as the smart flash card application of the electronic device, can establish two GPS fences corresponding to the first virtual card according to the GPS location information and GPS accuracy. Wherein, the size of these two GPS fences is different, that is, a large fence and a small fence, the large fence corresponding to the first virtual card can be the first fence in the embodiment of the present application, and the small fence corresponding to the first virtual card It may be the second fence in the embodiment of this application. For example, the two GPS fences are two fences centered on the GPS location information and having different radii. That is to say, for a first virtual card, when the user first uses the first virtual card to complete a transaction at a certain card swiping point, the smart flash card application of the electronic device can establish a large fence and a small fence corresponding to the first virtual card .

Wherein, the radius of the large fence can be a preset length. The preset length can be set according to the actual situation, and the implementation of the present application is not limited thereto, for example, 1 kilometer. The radius of the small fence can be N times the GPS accuracy, and the radius of the small fence is smaller than the radius of the big fence. N can be set according to the actual situation, which is not limited in the implementation of the present application. For example, N is 5, and the GPS accuracy of 5 times is smaller than the radius of the large fence.

Among them, when the radius of the small fence is 5 times the GPS accuracy, the probability that the user's real location is outside the range of the small fence when swiping the card is about one in a million, that is, the small fence can more accurately include the real location of the user when swiping the card. Location.

After the electronic device determines that the user enters the GPS fence, it takes 1-2 seconds until the electronic device activates the first virtual card corresponding to the GPS fence. In order to avoid that within this time period, the user has reached the card swiping point in the corresponding small fence, but the electronic device has not activated the first virtual card corresponding to the small fence, the electronic device, such as the smart flash card application of the electronic device, can Set the radius of the small fence to be greater than 50 meters and less than 500 meters. That is, when the 5 times GPS accuracy is less than 50 meters, the radius of the small fence can be set to 50 meters. When the 5 times GPS accuracy is greater than 500 meters, the radius of the small fence can be set to 500 meters. When the 5 times GPS accuracy is greater than 50 meters and less than 500 meters, the radius of the small fence can be set to 5 times the GPS accuracy.

When the user has fewer card swiping points, the GPS fence corresponding to the virtual card established by the electronic device may be less, or when the distance between different card swiping points is very far, the distance between the GPS fences corresponding to the virtual card established by the electronic device may It will be far away, and there will be no overlapping areas between the large fences corresponding to different virtual cards. At this time, the electronic device can accurately determine the virtual card that needs to be activated through the large fence, so that when the user enters the large fence, the electronic device selects the corresponding virtual card to activate, ensuring that the electronic device is activated before the user arrives at the card swiping point for transactions. The corresponding virtual card has been activated.

For example, as shown in FIG. 7 , taking a GPS fence corresponding to the first virtual card as an example, a GPS fence corresponding to the first virtual card is established on the electronic device, and the GPS fence may be a large fence 02 . When the user 01 arrives at position A with the electronic device, that is, the user enters the big fence 02 with the electronic device, the electronic device can activate the first virtual card corresponding to the big fence 02, ensuring that the user arrives at the card swiping point corresponding to the big fence 02 before making a transaction , the electronic device has activated the corresponding first virtual card. When the user 01 moves from position A to position B with the electronic device, the user is always within the range of the large fence 02, and the electronic device can keep the first virtual card corresponding to the large fence 02 in an activated state. When the user 01 arrives at position B with the electronic device, that is, the user leaves the big fence 02 with the electronic device, and the first virtual card corresponding to the big fence 02 is not the default card, the electronic device can remove the first virtual card corresponding to the big fence 02. Activate, and reactivate the default card.

In some examples, as shown in FIG. 7 , taking the geofence corresponding to the first virtual card as an example, when the user arrives at position A with the electronic device, that is, the user enters the large fence 02 with the electronic device, when the user 01 When holding the electronic device from position A to position C, the electronic device determines that the user has been in the big fence 02 for more than a preset period of time, and the electronic device can activate the first virtual card corresponding to the big fence 02.

It should be noted that the electronic device, such as the smart flash card application of the electronic device, can also establish and store GNSS fences corresponding to other virtual cards, and the other virtual cards can be the first virtual card among the multiple virtual cards included in the electronic device. other virtual cards. The GNSS fence of this other virtual card can comprise: the second GNSS fence (such as GPS fence) corresponding to the second virtual card, and the second GNSS fence can comprise a large fence and a small fence, and the large fence corresponding to the second virtual card can be The third fence in the embodiment of the present application, the small fence corresponding to the second virtual card can be the fourth fence in the embodiment of the present application, the range of the large fence in the second GNSS fence is larger than the small fence in the second GNSS fence range. There may be one or multiple second virtual cards, which is not limited in this embodiment of the present application.

When there are many card swiping points of the user, there may be more GPS fences established by the electronic device, or the distance between different card swiping points is relatively close, that is, the distance between the GPS fences established by the electronic device may be relatively short, and different virtual cards correspond to There may be overlapping areas between large fences. However, the possibility of overlapping areas between the small fences corresponding to different virtual cards is small. At this time, the electronic device can accurately determine the virtual card that needs to be activated through the small fence, so that the electronic device has automatically selected and activated the correct virtual card before the user arrives at the card swiping point to swipe the card.

It can be understood that the GPS fences corresponding to different first virtual cards may overlap. For example, there is an overlapping area between the large fence corresponding to the first virtual card 1 and the small fence corresponding to the first virtual card 2, or the There is an overlapping area between the large fence corresponding to 3 and the large fence corresponding to the first virtual card 4, or there may be an overlapping area between the small fence corresponding to the first virtual card 5 and the small fence corresponding to the first virtual card 6. In the overlapping area, the electronic device cannot determine which virtual card corresponding to the GPS fence is selected and activated.

Therefore, in this embodiment, after the smart flash card application of the electronic device establishes the GPS fence corresponding to the first virtual card (that is, the large fence and the small fence), the priorities of different GPS fences can be set for use in different GPS fences. In the overlapping area of the GPS fence corresponding to a virtual card, the electronic device can select the corresponding first virtual card to activate.

For example, an electronic device, such as a smart flash card of an electronic device, can set the priority of the large fence to be lower than that of the small fence, so that when the user holds the electronic device and enters the overlapping area between the large fence and the small fence corresponding to different first virtual cards , the electronic device can activate the virtual card corresponding to the small fence.

And when the user holds the electronic device and enters the overlapping area between the large fence and the large fence corresponding to different first virtual cards, or when the overlapping area between the small fence and the small fence corresponding to different first virtual cards, the priority of the GPS fence is the same. The electronic device in the overlapping area cannot determine which corresponding first virtual card is selected and activated.

For example, as shown in Figure 8, taking the geographic fence corresponding to the first virtual card as an example, a plurality of GPS fences 03 corresponding to the first virtual card are set up on the electronic device, and the GPS fence 03 is a large fence, which can also be For a small fence. When the user 01 arrives at location A with the electronic device, that is, the user enters a GPS fence 03 with the electronic device, the electronic device can activate the first virtual card corresponding to the GPS fence 03 . And when the user 01 arrives at position B with the electronic device, that is, the user enters the overlapping area of multiple GPS fences 03, and when the multiple GPS fences 03 are all large or small fences, the electronic device cannot Determine which corresponding virtual card is selected and activated.

Therefore, in this embodiment, the electronic device, such as the smart flash card application of the electronic device, can also set the priorities of different first virtual cards for overlapping between the large fences corresponding to the different first virtual cards. The electronic device can select the corresponding first virtual card to activate in the area, or in the overlapping area between the small fences corresponding to the different first virtual cards and the small fences.

For example, after the smart flash card application of the electronic device determines a plurality of first virtual cards, different priorities may be set and saved for the plurality of first virtual cards. For example, the first virtual card includes a community access control card, a public transportation card, and a white card (such as a smart door lock card). Electronic devices, such as the smart flash card application of electronic devices, can set the priority of community access control cards higher than that of public transportation cards, and the priority of public transportation cards is higher than that of smart door lock cards. That is, when the electronic device determines that the user can hold the electronic device to enter the large fence corresponding to the community access control card and also enter the large fence corresponding to the public transportation card, since the priority of the community access control card is higher than that of the public transportation card, the electronic device can control the community access control. The card is activated.

It should be noted that when the electronic device establishes the GPS fence corresponding to the virtual card according to the GPS position information and the GPS accuracy, one GPS fence or more than two GPS fences can also be established. When building more than two GPS fences, the radius of the two or more GPS fences varies.

For example, when a GPS fence is established, the GPS fence may be a circle centered on the GPS location information and with a preset length as the radius. When two or more GPS fences are established, the two or more GPS fences may be circles centered on GPS position information and with different preset lengths as radii.

In some other embodiments, the GPS fence may also be a polygonal area with a plurality of geographic location coordinate points as vertices, and the vertices are connected. The electronic device can obtain a plurality of geographic location coordinate points, so as to establish a GPS fence corresponding to the swiping point of the first virtual card.

S604. The smart flash card application of the electronic device saves the geo-fence corresponding to the first virtual card.

The geo-fence corresponding to the first virtual card may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the embodiment of the present application, the geographic fence corresponding to the first virtual card is taken as an example for schematic illustration.

After establishing the GPS fence corresponding to the first virtual card (that is, the large fence and the small fence), the electronic device, such as the smart flash card application in the electronic device, can store the first virtual card and the GPS fence correspondingly in the memory of the electronic device. For example, the smart flash card application of the electronic device may store the correspondence between the identifier of the first virtual card and the identifier of the GPS fence in the memory of the electronic device. The identifier of the first virtual card may be the AID of the first virtual card, or may be the ID of the first virtual card. The identification of the GPS fence may be the ID of the GPS fence. Table 2 shows the correspondence between the identifier of the first virtual card stored in the memory of the electronic device and the identifier of the GPS fence.

Table 2

As shown in Table 2, the cell access control card marked as ID1 corresponds to the GPS fences marked as ID2 and ID3, the GPS fence marked as ID2 is a large fence, and the GPS fence marked as ID3 is a small fence. The public transportation card marked as AID1 corresponds to the GPS fences marked as ID4 and ID5, the GPS fence of ID4 is a large fence, and the GPS fence marked as ID5 is a small fence. The smart door lock card marked as AID2 corresponds to the GPS fence marked as ID6 and ID7, the GPS fence of ID6 is a large fence, and the GPS fence marked as ID7 is a small fence.

In some examples, the electronic device, such as the smart flash card application of the electronic device, may also delete the stored GPS fence corresponding to the first virtual card.

For example, an electronic device, such as a smart flash card application of an electronic device, can determine whether the GPS fence corresponding to the stored first virtual card has reached the corresponding validity period, and the validity period can be set according to the actual situation. When the GPS fence reaches the corresponding validity period Next, the electronic device, such as the smart flash card application of the electronic device can remove the GPS fence.

As another example, when the electronic device, such as the smart flash card application of the electronic device determines that there are many GPS fences corresponding to the first virtual card stored in the electronic device, the electronic device can delete some of the GPS fences according to the actual situation, such as within a preset period of time. There is no GPS fence used, the electronic device can remove the GPS fence.

S605. The smart flash card application of the electronic device sends the geo-fence corresponding to the first virtual card to the sensor hub of the electronic device.

The geo-fence corresponding to the first virtual card may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the embodiment of the present application, the geographic fence corresponding to the first virtual card is taken as an example for schematic illustration.

For example, with reference to the example in FIG. 4, after the smart flash card application in the electronic device establishes the GPS fence corresponding to the first virtual card, the smart flash card application can store the information between the first virtual card identifier and the corresponding GPS fence identifier. Correspondence. The smart flash card application of the electronic device can also send the established GPS fence to the sensorhub of the electronic device.

Specifically, the above S605 may include the following S6051-S6053.

S6051. The smart flash card application sends the geo-fence corresponding to the first virtual card to the application in the system service.

The geo-fence corresponding to the first virtual card may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the embodiment of the present application, the geographic fence corresponding to the first virtual card is taken as an example for schematic illustration.

It can be understood that when the geographic fence corresponding to the first virtual card is a GPS fence, the application in the system service may be a GPS application. When the geofence corresponding to the first virtual card is also a Wi-Fi geofence, the application in the system service may be a Wi-Fi application.

The smart flash card application sends the GPS fence corresponding to the first virtual card (that is, a circle whose center is the corresponding GPS location information and whose radius is the corresponding length) and the identification of the GPS fence to the GPS application. The established GPS fence and the identification of the GPS fence are stored in the GPS application.

S6052. The application in the system service sends the geo-fence corresponding to the first virtual card to the sensor hub.

The geo-fence corresponding to the first virtual card may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the embodiment of the present application, the geographic fence corresponding to the first virtual card is taken as an example for schematic illustration.

It can be understood that when the geographic fence corresponding to the first virtual card is a GPS fence, the application in the system service may be a GPS application. When the geofence corresponding to the first virtual card is also a Wi-Fi geofence, the application in the system service may be a Wi-Fi application.

After the GPS application receives the GPS fence corresponding to the first virtual card sent by the smart flash card application, the GPS application can send the GPS fence corresponding to the first virtual card (that is, the GPS fence and the identification of the GPS fence that has been established) to the sensorhub.

S6053. The sensor hub receives the geo-fence corresponding to the first virtual card.

The geo-fence corresponding to the first virtual card may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the embodiment of the present application, the geographic fence corresponding to the first virtual card is taken as an example for schematic illustration.

The GPS fence corresponding to the first virtual card sent by the smart card application of the electronic device to the sensorhub may be the large fence corresponding to the first virtual card, or the small fence corresponding to the first virtual card, or the first virtual card. A virtual card corresponds to a large fence and a small fence.

In some examples, the electronic device, such as the smart flash card application of the electronic device, can determine the type of GPS fence that the smart flash card application sends to the sensorhub according to the number of GPS fences stored in the electronic device.

For example, when the number of GPS fences stored in the electronic device is large, that is to say, when the user uses a virtual card to swipe a large number of point cards, there is less possibility of overlapping areas between the small fences corresponding to different virtual cards. Therefore, the smart flash card application of the electronic device can send the small fence corresponding to the first virtual card to the sensorhub.

As another example, when the number of GPS fences stored in the electronic device is small, that is to say, when the user uses a virtual card to swipe fewer cards, the possibility of overlapping areas between the large fences corresponding to different virtual cards is relatively small. Therefore, the smart flash card application of the electronic device can send the large fence corresponding to the first virtual card to the sensorhub.

For another example, when the number of GPS fences stored in the electronic device is moderate, that is to say, when the user uses a virtual card to swipe a moderate number of cards, the smart flash card application of the electronic device can send the small fence corresponding to the first virtual card to sensorhub and a large fence.

In some examples, the electronic device, such as the smart flash card application of the electronic device, can also send the identification of the GPS fence that needs to be deleted to the sensorhub of the electronic device, and the sensorhub can delete the GPS fence corresponding to the received GPS fence identification, thereby sensorhub no longer monitors whether the user enters the GPS fence.

It should be noted that due to weather, card swiping points located in basements, etc., there may be errors in the GPS accuracy obtained by electronic devices. Since the radius of the small fence is determined based on GPS accuracy, there may also be errors in the small fence built by the electronic device.

In order to avoid errors in the GPS fence established by the electronic device, for a virtual card that has established a GPS fence, the electronic device can obtain the user's card at the corresponding card swiping point every preset period of time (such as 1 day, or 1 month). GPS location information and GPS accuracy, re-establish the GPS fence corresponding to the virtual card according to the GPS location information and GPS accuracy, and update the GPS fence stored in the electronic device. For the process of the electronic device re-establishing the GPS fence corresponding to the virtual card, reference may be made to the above-mentioned steps S601-S605, which will not be repeated in this embodiment of the present application.

After storing the GPS fence corresponding to the virtual card, the electronic device can periodically obtain the GPS location information of the electronic device, and determine the virtual card that needs to be activated according to the user's GPS location information and the corresponding relationship between the stored virtual card and the GPS fence , that is, the correct virtual card is automatically selected and activated before the user swipes the card.

Specifically, this process may be called a "virtual card switching" process. As shown in FIG. 9, the "virtual card switching" process may include the following S901-S911.

S901. The sensor hub of the electronic device acquires current geographic location information of the electronic device.

The current geographic location information of the electronic device may be GNSS location information, corresponding Cell information, corresponding Wi-Fi information, or other types of location information, which is not limited in this embodiment of the present application. . The GNSS location information may be GPS location information, GLONASS location information, Beidou location information, QZSS location information, or SBAS location information. The specific type of GNSS location information is not limited in this application.

For ease of understanding, in the embodiment of the present application, the current geographic location information of the electronic device is taken as GPS location information as an example for schematic illustration.

An electronic device, such as a sensor hub (sensorhub) in the electronic device, may acquire current GPS location information of the electronic device in real time or periodically. The current GPS location information of the electronic device may be the current latitude and longitude coordinates of the electronic device.

For example, referring to the example in FIG. 4 , the sensorhub can obtain the user's GPS location information from the short-distance chip in real time or periodically. Specifically, the above S901 may include the following S9011-S9012.

S9011. The short-distance chip sends the current geographic location information of the electronic device to the sensor hub.

The current geographic location information of the electronic device may be GNSS location information, corresponding Cell information, corresponding Wi-Fi information, or other types of location information, which is not limited in this embodiment of the present application. .

The GNSS location information may be GPS location information, GLONASS location information, Beidou location information, QZSS location information, or SBAS location information. The specific type of GNSS location information is not limited in this application.

For ease of understanding, in the embodiment of the present application, the current geographic location information of the electronic device is taken as GPS location information as an example for schematic illustration.

The short-distance chip can send the current GPS location information of the electronic device to the sensorhub in real time or periodically.

S9012. The sensor hub receives current geographic location information of the electronic device.

The current geographic location information of the electronic device may be GNSS location information, corresponding Cell information, corresponding Wi-Fi information, or other types of location information, which is not limited in this embodiment of the present application. .

The GNSS location information may be GPS location information, GLONASS location information, Beidou location information, QZSS location information, or SBAS location information. The specific type of GNSS location information is not limited in this application.

For ease of understanding, in the embodiment of the present application, the current geographic location information of the electronic device is taken as GPS location information as an example for schematic illustration.

S902. The sensor hub of the electronic device determines whether the user enters the geofence according to the current geographic location information of the electronic device.

The current geographic location information of the electronic device may be GNSS location information, corresponding Cell information, corresponding Wi-Fi information, or other types of location information, which is not limited in this embodiment of the present application. .

The GNSS location information may be GPS location information, GLONASS location information, Beidou location information, QZSS location information, or SBAS location information. The specific type of GNSS location information is not limited in this application.

The geo-fence may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application.

The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of GNSS geo-fence is not limited in this application.

For ease of understanding, in the embodiment of the present application, the current geographic location information of the electronic device is taken as GPS location information as an example for schematic illustration. That is, the sensor hub of the electronic device determines whether the user enters the corresponding GPS fence according to the current GPS location information of the electronic device.

When the user moves with the electronic device, the GPS position information of the electronic device is the GPS position information of the user. Therefore, according to the current GPS location information of the electronic device, that is, the current GPS location information of the user, that is, according to the current GPS location information of the electronic device, it can also be determined whether the user enters the GPS fence. That is, the electronic device monitors whether the position of the electronic device reaches the range of the GPS fence.

The electronic device, such as the sensorhub of the electronic device, can determine whether the user enters the GPS fence according to the current GPS position information of the electronic device. When the electronic device determines that the current latitude and longitude coordinates of the electronic device are within the range of a certain GPS fence, it is determined that the user has entered the GPS fence; when the user's latitude and longitude coordinates are not within the range of the GPS fence, it is determined that the user has not entered the GPS fence . For example, the sensor hub of an electronic device can use a fence algorithm, such as the GPS fence algorithm, to determine whether the user has entered the GPS fence according to the current GPS location information of the electronic device. When it is determined that the user has entered the GPS fence, it can determine the GPS fence that the user entered logo.

When the user enters the GPS fence, he may enter one GPS fence or multiple GPS fences. The user enters a GPS fence, that is, the current GPS location information of the electronic device is within the range of a GPS fence, and the GPS fence can be a large fence or a small fence. For example, when a user enters a fence, it may be that the user enters the first fence corresponding to the first virtual card, or it may be that the user enters the second fence corresponding to the first virtual card. The user enters multiple GPS fences, that is, the current GPS location information of the electronic device is located in the overlapping area of the GPS fences. The overlapping area can be the overlapping area of multiple small fences, or the overlapping area of multiple large fences, or it can be The overlapping area of multiple large fences and small fences.

For example, when the user enters the overlapping area of multiple fences, it may be that the user enters the overlapping area of the first fence corresponding to the first virtual card and the third fence corresponding to the second virtual card, or it may be that the user enters the first fence corresponding to the first virtual card. The overlapping area of the second fence and the fourth fence corresponding to the second virtual card can also be the overlapping area where the user enters the first fence corresponding to the first virtual card and the fourth fence corresponding to the second virtual card, or the user enters the fourth fence corresponding to the second virtual card. The overlapping area of the second fence corresponding to a virtual card and the fourth fence corresponding to the second virtual card.

An electronic device, such as a sensor hub of an electronic device, can use a fence algorithm, such as a GPS fence algorithm, to determine whether the user has entered the GPS fence according to the current GPS location information of the electronic device, and determine whether the user has entered the GPS fence. The identification of the GPS fence the user entered. In a case where it is determined that the user has entered multiple GPS fences, identities of the multiple GPS fences that the user has entered may be determined.

For example, as shown in FIG. 4 , the sensorhub of the electronic device can obtain the GPS location information of the user from the short-distance chip in real time. Since the sensorhub stores the established GPS fence (that is, the corresponding GPS location information as the center, the circle with the corresponding length as the radius) and the logo of the GPS fence, the GPS fence algorithm in the sensorhub determines based on the current GPS location information of the electronic device. Whether the user enters the GPS fence, and the identifier of the GPS fence that the user enters. The sign of the GPS fence that the sensorhub determines to be entered by the user may be a sign of a large fence or a sign of a small fence. The identifier of the GPS fence that the sensorhub determines to be entered by the user may be one or more.

When the electronic device determines that the user has not entered the GPS fence, the electronic device can continue to obtain the current GPS location information of the electronic device, and determine whether the user has entered the GPS fence according to the current GPS location information of the electronic device, that is, the electronic device can re-execute the above-mentioned S901-S902.

It can be understood that when the electronic device determines that the user does not enter the range of the GPS fence, the electronic device, such as the smart flash card application of the electronic device, can keep the default card activated, or activate the default card. For example, the default card stored in the electronic device is a smart door lock card. When the electronic device determines that the user enters the GPS fence corresponding to the public transport card according to the user's GPS location information, the electronic device can activate the public transport card. When the electronic device determines that the user has left the GPS fence corresponding to the public transportation card according to the user's GPS location information, that is, the electronic device determines that the user has not entered the GPS fence, the electronic device can deactivate the public transportation card, and re-activate the default card (such as Smart door lock card) activation. For another example, when the electronic device determines according to the user's GPS location information that the user enters the GPS fence corresponding to the default card (that is, the smart door lock card), the electronic device may keep the default card activated. When the user leaves the GPS fence corresponding to the default card, that is, the electronic device determines that the user has not entered the GPS fence, the electronic device may still keep the default card activated.

In some embodiments, the electronic device, such as the sensorhub of the electronic device, can use a fence algorithm, such as the GPS fence algorithm, to determine whether the user has left the GPS fence according to the current GPS location information of the electronic device, and if it is determined that the user has left the GPS fence , the identification of the GPS fence that the user leaves can be determined. The sensorhub of the electronic device can also use the GPS fence algorithm based on the current GPS location information of the electronic device to determine that the user has entered a certain GPS fence for more than the preset time. Determine the identity of the GPS fence that the user has entered for more than a preset duration.

When the electronic device determines that the user enters the GPS fence, the electronic device may execute S903-S911.

S903. When it is determined that the user enters the geo-fence, the sensor hub of the electronic device sends the identifier of the geo-fence entered by the user to the smart flash card application of the electronic device.

The geo-fence entered by the user may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

The identifier of the geo-fence may be an identifier corresponding to the GNSS geo-fence, may also be an identifier corresponding to the Cell geo-fence, and may also be an identifier corresponding to the Wi-Fi geo-fence.

For ease of understanding, in the embodiment of the present application, a GPS fence is taken as an example for a user to enter a geographic fence for schematic illustration. That is, the identifier of the geographical fence entered by the user is the identifier of the GPS fence entered by the user.

For example, with reference to the example in FIG. 4, the sensorhub of the electronic device can use the GPS fence algorithm to determine that when the user enters the GPS fence, the sensorhub of the electronic device can send the identification of one or more GPS fences that the user enters to the electronic device through the GPS application. Smart flash card application. Specifically, the above S903 may include the following S9031-S9032.

S9031. When determining that the user has entered the geo-fence, the sensor hub sends the identifier of the geo-fence entered by the user to the application in the system service.

The geo-fence entered by the user may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of GNSS geo-fence is not limited in this application.

The identifier of the geo-fence may be an identifier corresponding to the GNSS geo-fence, may also be an identifier corresponding to the Cell geo-fence, and may also be an identifier corresponding to the Wi-Fi geo-fence.

It can be understood that when it is determined that the user enters the GPS fence, the application in the system service may be a GPS application. When it is determined that the user enters the Wi-Fi geofence, the application in the system service may be a Wi-Fi application.

For ease of understanding, in the embodiment of the present application, a GPS fence is taken as an example for a user to enter a geographic fence for schematic illustration. That is, the identifier of the geographical fence entered by the user is the identifier of the GPS fence entered by the user, and the application in the system service is a GPS application.

The sensorhub can send the identification of the GPS fence that the user enters to the GPS application through the hardware connection layer.

S9032. The application in the system service sends the identifier of the geographical fence entered by the user to the smart card application.

The geo-fence entered by the user may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of GNSS geo-fence is not limited in this application.

The identifier of the geo-fence may be an identifier corresponding to the GNSS geo-fence, may also be an identifier corresponding to the Cell geo-fence, and may also be an identifier corresponding to the Wi-Fi geo-fence.

It can be understood that when it is determined that the user enters the GPS fence, the application in the system service may be a GPS application. When it is determined that the user enters the Wi-Fi geofence, the application in the system service may be a Wi-Fi application.

For ease of understanding, in the embodiment of the present application, a GPS fence is taken as an example for a user to enter a geographic fence for schematic illustration. That is, the identifier of the geographical fence entered by the user is the identifier of the GPS fence entered by the user, and the application in the system service is a GPS application.

After receiving the identification of the GPS fence entered by the user, the GPS application may send the identification of the GPS fence entered by the user to the smart flash card application.

In some embodiments, when the electronic device determines whether the user leaves a certain GPS fence, the electronic device, such as the sensorhub of the electronic device, may send the identification of the GPS fence that the user leaves to the electronic device, such as the smart card application of the electronic device. When the sensorhub of the electronic device determines that the user enters a certain GPS fence for more than a preset time, the electronic device, such as the sensorhub of the electronic device, sends the identification of the GPS fence that the user enters and the time that the user enters the GPS fence for more than a preset time to the electronic device, such as Smart flash card application for electronic devices.

For example, as shown in FIG. 7, taking the user entering the geofence as the GPS fence, and the logo of the user entering the geofence as the logo of the GPS fence as an example, when user 01 arrives at position A with the electronic device, that is, the user enters the large location with the electronic device. Fence 02, the sensorhub of the electronic device sends the identification of the GPS fence that the user enters to the smart flash card application of the electronic device. When the user 01 takes the electronic device from position A to position C, the electronic device determines that the time the user is in the large fence 02 exceeds the preset time length, and the electronic device can send the logo of the large fence and the user entering the large fence 02 beyond the preset time length Smart flash card application for electronic devices.

S904. The smart flash card application of the electronic device receives the identifier of the geofence entered by the user.

The identifier of the geo-fence may be an identifier corresponding to the GNSS geo-fence, may also be an identifier corresponding to the Cell geo-fence, and may also be an identifier corresponding to the Wi-Fi geo-fence, which is not limited in this embodiment of the present application.

For ease of understanding, in the embodiment of the present application, a GPS fence is taken as an example for a user to enter a geographic fence for schematic illustration. That is, the identifier of the geographical fence entered by the user is the identifier of the GPS fence entered by the user.

S905. The smart flash card application of the electronic device determines whether the geofence entered by the user is one.

The geo-fence entered by the user may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the embodiment of the present application, a GPS fence is taken as an example for a user to enter a geographic fence for schematic illustration.

The electronic device, such as the smart flash card application of the electronic device, can determine whether the user enters one or more GPS fences according to the number of received GPS fences entered by the user.

For example, continue to show in Figure 7, take the sensorhub of the electronic device to send the identification of the GPS fence that the user enters, and the smart flash card application that the user enters the GPS fence to the electronic device for a preset period of time, that is, when the user 01 holds the electronic When the device arrives at position C from position A, the electronic device determines that the user has been in the large fence 02 for more than the preset time period, and the electronic device can send the identification of the large fence 02 and the user's entry into the large fence 02 for more than the preset time length to the electronic device. Smart flash card application. The smart flash card application of the electronic device receives the identification of the fence entered by the user and when the user enters the fence for more than a preset period of time, the smart flash card application of the electronic device can determine whether the GPS fence entered by the user is one.

As another example, as shown in FIG. 8 , it is taken that the electronic device establishes multiple GPS fences 03 corresponding to the first virtual cards as an example. When the user 01 arrives at position A with the electronic device, the sensorhub of the electronic device sends the identification of a GPS fence that the user enters to the smart flash card application of the electronic device. When the user takes the electronic device from position A to position B, the sensorhub of the electronic device can determine that the user has entered multiple GPS fences 03, and the sensorhub of the electronic device can send the identification of the multiple GPS fences 03 to the smart flash card of the electronic device application, so that the smart flash card application of the electronic device can determine whether there are multiple GPS fences entered by the user.

In a case where the electronic device determines that the GPS fence entered by the user is one, the electronic device may execute S906. When the electronic device determines that there are multiple GPS fences entered by the user, the electronic device may execute S907-S911.

S906. The smart flash card application of the electronic device activates the virtual card corresponding to the geo-fence.

The geo-fence entered by the user may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the embodiment of the present application, a GPS fence is taken as an example for a user to enter a geographic fence for schematic illustration. That is, the virtual card corresponding to the geographic fence is the virtual card corresponding to the GPS fence. In the case that the electronic device determines that the GPS fence that the user enters is one, the electronic device, such as the smart flash card application of the electronic device, can use the corresponding relationship between the identification of the virtual card stored in the memory of the electronic device and the identification of the GPS fence , activate the virtual card corresponding to the GPS fence. For example, the smart flash card application of the electronic device receives the identification of the first fence or the second fence, that is, the location of the electronic device reaches the GPS fence corresponding to the first virtual card, and the smart flash card application of the electronic device can The corresponding relationship between the identifier of the virtual card stored in the memory of the device and the identifier of the GPS fence activates the first virtual card.

For example, as shown in (a) in Figure 10, taking the geo-fence entered by the user as an example of a GPS fence, when the user arrives at position A with the electronic device, the electronic device determines that the user enters the fence according to the current GPS location information of the electronic device. 1. The smart flash card application of the electronic device activates the virtual card corresponding to the fence 1 according to the corresponding relationship between the virtual card identifier stored in the electronic device and the GPS fence identifier. When the user moves from position A to position B with the electronic device, the electronic device determines that the GPS fence that the user enters is always fence 1 according to the current GPS location information of the electronic device, and the smart flash card application of the electronic device can keep fence 1 corresponding The virtual card of is active. When the user reaches position C with the electronic device, the electronic device determines that only fence 2 is the only GPS fence entered by the user according to the current GPS location information of the electronic device, and the smart flash card application of the electronic device activates the virtual card corresponding to fence 2. When the user moves the electronic device from position C to position D, the electronic device determines that the GPS fence entered by the user is always fence 2 according to the current GPS location information of the electronic device, and the smart flash card application of the electronic device can keep fence 2 corresponding The virtual card of is active. When the user leaves position D with the electronic device, the electronic device determines that the user has not entered the GPS fence according to the current GPS location information of the electronic device. When the virtual card corresponding to fence 2 is not the default card, the smart flash card application of the electronic device can use Deactivate the virtual card corresponding to fence 2, and activate the default card.

When the electronic device determines that the user has entered multiple GPS fences, the electronic device may activate the virtual card corresponding to the GPS fence with the highest priority according to the priorities of the multiple GPS fences. For example, continuing to refer to (a) in Figure 10, taking the geofence that the user enters as a GPS fence as an example, when the user arrives at location B with the electronic device, the electronic device determines that the user enters the location according to the current GPS location information of the electronic device. In the overlapping area between fence 1 and fence 2, the smart flash card application of the electronic device can determine which fence corresponds to the virtual card that the user activates when fence 1 corresponds to the overlapping area of fence 2 according to the priority of fence 1 and fence 2. Specifically, the electronic device may execute S907-S911.

S907. The smart flash card application of the electronic device determines whether there is one geo-fence with the highest priority among the multiple geo-fences entered by the user.

The geo-fence entered by the user may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the embodiment of the present application, a GPS fence is taken as an example for a user to enter a geographic fence for schematic illustration. That is, the smart flash card application of the electronic device determines whether there is one GPS fence with the highest priority among the multiple GPS fences entered by the user.

When the electronic device determines that there are multiple GPS fences that the user enters, the electronic device, such as the smart flash card application of the electronic device, can determine the priority among the multiple GPS fences that the user enters according to the preset priorities of different GPS fences. Whether the highest level GPS fence is one.

In a case where the electronic device determines that the GPS fence with the highest priority among the multiple GPS fences entered by the user is one, the electronic device may execute S908. When the electronic device determines that there are multiple GPS fences with the highest priority among the multiple GPS fences entered by the user, the electronic device can further activate the virtual card with the highest priority according to the priorities of the virtual cards corresponding to the multiple GPS fences . Specifically, the electronic device may execute the following S909-S911.

S908. The smart flash card application of the electronic device activates the virtual card corresponding to the geographical fence with the highest priority.

The geo-fence entered by the user may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the embodiment of the present application, a GPS fence is taken as an example for a user to enter a geographic fence for schematic illustration. That is, the geofence with the highest priority is the GPS fence.

When the electronic device determines that the GPS fence with the highest priority among the multiple GPS fences entered by the user is one, the electronic device, such as the smart card application of the electronic device, can activate the virtual card corresponding to the GPS fence with the highest priority. For example, when the electronic device determines that the user's GPS location information is located in the overlapping area of a large fence and a small fence, since the priority of the large fence is lower than that of the small fence, the smart flash card application of the electronic device can set the small fence For virtual card activation. For example, the smart flash card application of the electronic device receives that the GPS fence entered by the user is the identification of the second fence, and the identification of the third fence, that is, the position of the electronic device reaches the small fence corresponding to the first virtual card, and the second virtual card Within the range of the corresponding large fence, since the second fence is a small fence and the third fence is a large fence, that is, the priority of the second fence is higher than that of the third fence, and the smart flash card application of the electronic device can set the first The virtual card is activated.

For example, in conjunction with (a) in FIG. 10 , take the geofence entered by the user as a GPS fence, fence 1 as a large fence, and fence 2 as a small fence as an example, that is, the priority of fence 2 is higher than that of fence 1. When the user moves from position B to position C with the electronic device, the electronic device determines that the user enters the overlapping area between fence 1 and fence 2 according to the current GPS position information of the electronic device, and the smart flash card application of the electronic device can With the priority of fence 2, activate the virtual card corresponding to fence 2.

S909. The smart flash card application of the electronic device determines whether there is only one virtual card with the highest priority among the virtual cards corresponding to multiple geo-fences with the highest priority.

The geo-fence entered by the user may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the embodiment of the present application, a GPS fence is taken as an example for a user to enter a geographic fence for schematic illustration. That is, multiple geofences with the highest priority are GPS fences.

When the electronic device determines that there are multiple GPS fences with the highest priority among the multiple GPS fences entered by the user, the electronic device, such as the smart flash card application of the electronic device, can determine the priority according to the priorities of different virtual cards preset. Whether the virtual card with the highest priority among the virtual cards corresponding to multiple GPS fences with the highest level is one.

In the case that the electronic device determines that the virtual card with the highest priority is one of the virtual cards corresponding to multiple GPS fences with the highest priority, the electronic device, such as the smart flash card application of the electronic device, can activate the virtual card with the highest priority. Specifically, the electronic device may execute the following S910.

When the electronic device determines whether there are multiple virtual cards with the highest priority corresponding to multiple GPS fences with the highest priority, the electronic device may activate the virtual card corresponding to the GPS fence that the user enters last. Specifically, the electronic device may execute the following S911.

S910. The smart flash card application of the electronic device activates the virtual card with the highest priority.

The geo-fence entered by the user may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the embodiment of the present application, a GPS fence is taken as an example for a user to enter a geographic fence for schematic illustration.

In the case that the electronic device determines that there are multiple virtual cards with the highest priority, the electronic device, such as the smart flash card application of the electronic device, can activate the virtual card with the highest priority.

For example, the smart flash card application of the electronic device receives that the GPS fence entered by the user is the first fence, the third fence, or the second fence, and the fourth fence, that is, the location of the electronic device Reach the large fence corresponding to the first virtual card, and reach the range of the large fence corresponding to the second virtual card, or, the position of the electronic device reaches the small fence corresponding to the first virtual card, and reaches the small fence corresponding to the second virtual card Within the scope of the electronic device, for example, the smart flash card application of the electronic device can determine the priority of the first virtual card and the priority of the second virtual card. In the case that the priority of the first virtual card is higher than that of the second virtual card, the smart flash card application of the electronic device can activate the first virtual card. In the case that the priority of the first virtual card is lower than that of the second virtual card, the smart flash card application of the electronic device can activate the second virtual card.

For example, as shown in (b) in Fig. 10, the geographical fence entered by the user is a GPS fence, the white card fence and the bus fence are all small fences, and the priority of the white card is lower than that of the public transportation card as an example. When the user moves from position E to position F with the electronic device, the electronic device determines that the user enters the overlapping area between the white card fence and the bus fence according to the current GPS location information of the electronic device. Both the white card fence and the bus fence are small fences. , that is, both the white card fence and the bus fence have the same priority, and the smart flash card application of the electronic device can further determine the priority of the virtual card corresponding to the white card fence and the bus fence, because the virtual card corresponding to the bus fence is the public transportation card. The priority is the highest, and the virtual card with the highest priority is one, and the smart flash card application of the electronic device can activate the public transportation card.

S911. The smart flash card application of the electronic device activates the virtual card corresponding to the last geofence entered by the user.

The geo-fence entered by the user may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the embodiment of the present application, a GPS fence is taken as an example for a user to enter a geographic fence for schematic illustration.

In the case that the electronic device determines that there are multiple virtual cards with the highest priority, the electronic device, such as the smart flash card application of the electronic device, can obtain the mobile trend of the user, that is, the mobile trend of the electronic device. According to the mobile trend of the user, the The virtual card corresponding to the GPS fence that the user entered last is activated.

For example, the position of the electronic device reaches the large fence corresponding to the first virtual card, and reaches the range of the large fence corresponding to the second virtual card, or, the position of the electronic device reaches the small fence corresponding to the first virtual card, and reaches the range of the second virtual card. Within the range of the small fence corresponding to the virtual card, when the electronic device, such as the smart flash card application of the electronic device, determines that the priority of the first virtual card is the same as that of the second virtual card, the electronic device, such as the smart flash card of the electronic device, The application can obtain the mobile trend of the electronic device. When the fence corresponding to the first virtual card is the fence on the mobile trend, that is, when the user finally enters the fence corresponding to the first virtual card, the smart flash card application of the electronic device can set the The first virtual card is activated. When the fence corresponding to the second virtual card is the fence on the mobile trend, that is, when the user enters the fence corresponding to the second virtual card last, the smart flash card application of the electronic device can activate the second virtual card.

Electronic devices, such as the sensorhub of the electronic device, can obtain GPS location information of the electronic device at different times from the short-distance chip, and determine the user's movement trend according to the GPS location information of the electronic device at different times.

For example, as shown in Figure 4, when the smart flash card application of the electronic device determines that there are multiple virtual cards with the highest priority, the smart flash card application of the electronic device obtains the user's movement trend from the sensorhub through the GPS application, and according to the user's mobile Trend, activate the virtual card corresponding to the GPS fence that the user entered last. Sensorhub can obtain GPS location information of electronic devices at different times from short-distance chips in real time or periodically, and determine the user's movement trend according to the GPS location information of electronic devices at different times.

For example, in conjunction with (c) in Figure 10, the geographical fence entered by the user is the GPS fence, and the white card fence 1 and the white card fence 2 are both small fences, that is, the priority of the white card fence 1 and the white card fence 2 is the same, For example, the virtual cards corresponding to white card fence 1 and white card fence 2 have the same priority. When the user arrives at position G with the electronic device, the electronic device determines that the user enters the white card fence 1 according to the current GPS location information of the electronic device, and the electronic device activates the virtual card corresponding to the white card fence 1 . When the user arrives at position H with the electronic device, the electronic device determines that the user enters the overlapping area of white card fence 1 and white card fence 2 according to the current GPS location information of the electronic device. The virtual card corresponding to white card fence 1 has the same priority as the virtual card corresponding to white card fence 2. At this time, the electronic device, such as the smart flash card application of the electronic device, can obtain the user's mobile trend from the sensorhub of the electronic device, that is, the user first enters the white card fence 1, from the white card fence 1 to the white card fence 1 and the white card The overlapping area of fence 2, that is to say, white card fence 2 is the GPS fence that the user enters last. The smart flash card application of the electronic device can activate the virtual card corresponding to the white card fence 2.

It should be noted that, in the case that the electronic device determines that there are multiple virtual cards with the highest priority, the electronic device, such as the smart flash card application of the electronic device, may also maintain the currently activated virtual card.

For example, as shown in (d) in Figure 10, the geographical fence entered by the user is the GPS fence, and the white card fence 1 and the white card fence 2 are both small fences, that is, the priority of the white card fence 1 and the white card fence 2 Similarly, the virtual cards corresponding to white card fence 1 and white card fence 2 have the same priority as an example. When the user arrives at position 1 with the electronic device, the electronic device determines that the user enters the white card fence 1 according to the current GPS position information of the electronic device, and the smart flash card application of the electronic device activates the virtual card corresponding to the white card fence 1. When the user arrives at position J with the electronic device, the electronic device determines that the user enters the overlapping area between white card fence 1 and white card fence 2 according to the current GPS location information of the electronic device. At this time, the electronic device, such as the smart flash card application of the electronic device, can keep the virtual card corresponding to the white card fence 1 in an activated state.

With the solution of this application, the smart flash card application of the electronic device can obtain the electronic device from the short-distance chip through the application in the system service, the hardware connection layer and the sensorhub when the user uses a certain virtual card for the first time to conduct transactions at a certain card swiping point. Current geographic location information and geographic accuracy. The smart flash card application establishes a geographic location fence corresponding to the virtual card according to the current geographic location information and geographic location accuracy of the electronic device. Afterwards, when the sensorhub determines that the user has entered the geo-location fence according to the geo-location information of the electronic device obtained from the short-distance chip, the sensorhub sends the identification of the geo-location fence that the user entered to the smart flash card application. The smart flash card application can activate the virtual card corresponding to the geo-location fence. That is, before the user swipes the card, the smart flash card application of the electronic device can use the geographic location fence to automatically activate the corresponding virtual card. When faced with different card swiping requirements, it can avoid the need for users to manually select a virtual card, thereby reducing the time for swiping cards and improving user experience.

Moreover, the solution of the present application can establish a corresponding geo-fence according to the GPS position information in the geographic location information and the GPS accuracy in the geographic location accuracy, and the GPS location information can be obtained by using the short-distance chip of the electronic device. The short-distance chip is the standard configuration of electronic equipment, so even if the electronic equipment does not have the Wi-Fi fence capability, that is, the electronic equipment does not have the sensorhub, or the sensorhub of the electronic equipment does not have the Wi-Fi fence capability, such as the sensorhub does not include Wi-Fi When using the Fi fence algorithm, the smart flash card application can still automatically activate the corresponding virtual card before the user swipes the card, which further improves the user experience.

In addition, the solution of this application determines the virtual card that needs to be activated by judging the priority of multiple geographic fences and the priority of virtual cards corresponding to multiple geographic fences when the user enters the range of multiple geographic fences. . It can avoid the need for the user to manually select the virtual card to activate when the user enters the range of multiple geo-fences, thereby further reducing the time for swiping the card and improving the user experience.

For ease of understanding, the virtual card switching method provided by the embodiment of the present application will be described below with reference to FIG. 11 . As shown in FIG. 11 , the virtual card switching method may include the following steps S1101-S1106.

S1101. The electronic device acquires a first virtual card.

For a specific implementation manner of obtaining the first virtual card by the electronic device, reference may be made to the implementation manner in S601 above. The embodiment of the present application will not be repeated here.

S1102. In the case that the electronic device uses the first virtual card to complete the data interaction for the first time at the first card swiping point, the electronic device obtains the geographic location information and the geographic location accuracy of the electronic device.

The geographic location information of the electronic device may be GNSS location information, corresponding Cell information, corresponding Wi-Fi information, or other types of location information, which is not limited in this embodiment of the present application. The GNSS location information may be GPS location information, GLONASS location information, Beidou location information, QZSS location information, or SBAS location information. The specific type of GNSS location information is not limited in this application.

The location accuracy of the electronic device may be GNSS location accuracy, corresponding Cell accuracy, corresponding Wi-Fi accuracy, or other types of location accuracy, which is not limited in this embodiment of the present application. The GNSS position information can be GPS accuracy, GLONASS accuracy, Beidou accuracy, QZSS accuracy or SBAS accuracy, etc.

For ease of understanding, in the embodiment of the present application, the current geographic location information of the electronic device is GPS location information, and the geographic location accuracy is GPS accuracy as an example for schematic illustration.

When an electronic device uses a first virtual card to interact with an NFC card reader for the first time at a certain card-swiping point (such as the first card-swiping point), it can obtain the current GPS location information and the specific implementation method of GPS accuracy, which can be referred to The above implementation in S602. The embodiment of the present application will not be repeated here.

S1103. The electronic device establishes and saves a geo-fence corresponding to the first virtual card according to the geographic location information and the geographic location accuracy.

The geo-fence corresponding to the first virtual card may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the embodiment of the present application, the geographic fence corresponding to the first virtual card is taken as an example for schematic illustration. The electronic device establishes a GPS fence corresponding to the first virtual card according to the GPS location information and GPS accuracy, which may be a large fence, a small fence, or a large fence and a small fence.

For a specific implementation manner in which the electronic device establishes and saves the GPS fence corresponding to the first virtual card according to the GPS location information and the GPS accuracy, reference may be made to the above implementation manners in S603-S605. The embodiment of the present application will not be repeated here.

S1104. The electronic device acquires geographic location information of the electronic device.

The geographic location information of the electronic device may be GNSS location information, corresponding Cell information, corresponding Wi-Fi information, or other types of location information, which is not limited in this embodiment of the present application. The GNSS location information may be GPS location information, GLONASS location information, Beidou location information, QZSS location information, or SBAS location information. The specific type of GNSS location information is not limited in this application.

For ease of understanding, in the embodiment of the present application, the current geographic location information of the electronic device is taken as GPS location information as an example for schematic illustration.

For a specific implementation manner in which the electronic device acquires the GPS location information of the electronic device, reference may be made to the implementation manner in S901 above. The embodiment of the present application will not be repeated here.

S1105. The electronic device determines whether the user enters the geo-fence according to the geographic location information of the electronic device.

The geographic location information of the electronic device may be GNSS location information, corresponding Cell information, corresponding Wi-Fi information, or other types of location information, which is not limited in this embodiment of the present application. The GNSS location information may be GPS location information, GLONASS location information, Beidou location information, QZSS location information, or SBAS location information. The specific type of GNSS location information is not limited in this application.

For ease of understanding, in the embodiment of the present application, the current geographic location information of the electronic device is taken as GPS location information as an example for schematic illustration.

The geo-fence entered by the user may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the embodiment of the present application, a GPS fence is taken as an example for a user to enter a geographic fence for schematic illustration. That is, the electronic device determines whether the user enters the GPS fence according to the GPS location information of the electronic device.

For a specific implementation manner in which the electronic device determines whether the user enters the GPS fence corresponding to the first virtual card according to the GPS location information of the electronic device, reference may be made to the implementation manner in S902 above. The embodiment of the present application will not be repeated here.

When the electronic device determines that the user enters the GPS fence corresponding to the first virtual card, the electronic device may execute S1106. When the electronic device determines that the user has not entered the GPS fence corresponding to the first virtual card, the electronic device can continue to obtain the GPS location information of the electronic device, and determine whether the user has entered the GPS fence according to the GPS location information of the electronic device, that is, the electronic The device may re-execute the above S1104.

S1106. The electronic device activates the first virtual card corresponding to the geo-fence.

The geo-fence entered by the user may be a GNSS geo-fence, a Cell geo-fence, a Wi-Fi geo-fence, or other types of geo-fences, which are not limited in this embodiment of the present application. The GNSS geo-fence can be GPS geo-fence, GLONASS geo-fence, Beidou geo-fence, QZSS geo-fence or SBAS geo-fence. The specific type of the GNSS geo-fence is not limited in this application.

For ease of understanding, in the embodiment of the present application, a GPS fence is taken as an example for a user to enter a geographic fence for schematic illustration.

The electronic device activates the first virtual card corresponding to the GPS fence, which may include:

When the electronic device determines that what the user enters is a GPS fence, the electronic device can activate the first virtual card corresponding to the GPS fence.

When the electronic device determines that the user has entered multiple GPS fences, the electronic device may further activate the first virtual card corresponding to the GPS fences according to the priorities of the GPS fences. For example, in the case of one of the GPS fences with the highest priority among the multiple GPS fences entered by the user, the electronic device may activate the first virtual card corresponding to the GPS fence with the highest priority among the multiple GPS fences entered by the user.

In the case that there are multiple GPS fences with the highest priority entered by the user, the electronic device may further activate the first virtual card corresponding to the GPS fence according to the priority of the first virtual card. For example, in the case that there is one virtual card with the highest priority among the first virtual cards corresponding to multiple GPS fences with the highest priority entered by the user, the electronic device may activate the first virtual card with the highest priority.

When there are multiple first virtual cards corresponding to the first GPS fences with the highest priority entered by the user, the electronic device can store the first virtual card corresponding to the GPS fence that the user entered last. activation.

Specifically, for a specific implementation manner in which the electronic device activates the first virtual card corresponding to the GPS fence, reference may be made to the implementation manners in S903-S911 above. The embodiment of the present application will not be repeated here.

With the solution of the present application, when a user uses a certain virtual card for the first time to conduct a transaction at a certain card swiping point, a geo-fence corresponding to the virtual card can be established according to the current geographic location information and geographic location accuracy of the electronic device. Afterwards, when the user enters the geographic fence again with the electronic device, the electronic device can automatically activate the virtual card corresponding to the geographic fence, so that the user can use the virtual card to complete transactions. That is, before the user swipes the card, the electronic device can automatically activate the corresponding virtual card by using the geo-fence. When faced with different card swiping requirements, it can avoid the need for users to manually select a virtual card, thereby reducing the time for swiping cards and improving user experience.

Moreover, the solution of the present application can establish a corresponding geo-fence according to the GPS position information in the geographic location information and the GPS accuracy in the geographic location accuracy, and the GPS location information can be obtained by using the short-distance chip of the electronic device. The short-distance chip is a standard configuration of electronic equipment, so even if the electronic equipment does not have the Wi-Fi fence capability, it can still realize the automatic activation of the corresponding virtual card before the user swipes the card, further improving the user experience.

In addition, the solution of the present application determines the virtual card to be activated by judging the priorities of the multiple geographic fences and the priorities of the virtual cards corresponding to the multiple geographic fences when the user enters the scope of multiple geographic fences. It can avoid the need for the user to manually select the virtual card to activate when the user enters the range of multiple geo-fences, thereby further reducing the time for swiping the card and improving the user experience. Corresponding to the methods in the preceding embodiments, the embodiments of the present application further provide a virtual card switching device. The device for switching virtual cards can be applied to electronic equipment to implement the methods in the foregoing embodiments. The functions of the device can be realized by hardware, and can also be realized by executing corresponding software by hardware. Hardware or software includes one or more modules corresponding to the above-mentioned functions.

For example, FIG. 12 shows a schematic structural diagram of a virtual card switching device 1200. As shown in FIG. 12, the virtual card switching device 1200 may include: an acquisition module 1201, a creation module 1202, a storage module 1203, and an activation module 1204.

Among them, the obtaining module 1201 can be used to obtain the GNSS position information and GNSS accuracy of the electronic device when the electronic device uses the first virtual card to complete the data interaction at the first card swiping point for the first time; the first virtual card is A virtual card among multiple virtual cards.

The establishment module 1202 can be used to establish the first GNSS fence corresponding to the first virtual card according to the GNSS position information and the GNSS accuracy, the first GNSS fence includes the first fence and the second fence, and the range of the first fence is larger than the second fence range.

The storage module 1203 may be configured to store the first GNSS fence corresponding to the first virtual card.

The activation module 1204 may be configured to activate the first virtual card when the electronic device detects that the position of the electronic device is within the range of the first GNSS fence.

In another possible implementation, the first fence is a circular area with the GNSS position information as the center and the preset length as the radius; the second fence is the GNSS position information as the center, and the GNSS accuracy of N times is A circular area with a radius; N is an integer greater than zero, and the preset length is greater than N times the GNSS accuracy.

In another possible implementation, the establishment module 1202 can also be used to establish GNSS fences of other virtual cards except the first virtual card in multiple virtual cards; wherein, the GNSS fences of other virtual cards include: the second The second GNSS fence corresponding to the virtual card, the second GNSS fence includes a third fence and a fourth fence, and the range of the third fence is larger than the range of the fourth fence.

The storage module 1203 may also be used to store the GNSS fences of other virtual cards except the first virtual card among the multiple virtual cards.

In another possible implementation, the activating module 1204 is specifically configured to be used when the electronic device monitors that the position of the electronic device is within the range of the first GNSS fence, but not within the range of the GNSS fences of other virtual cards to activate the first virtual card.

In another possible implementation manner, the activating module 1204 is specifically configured to, when the electronic device detects that the position of the electronic device reaches within the range of the second fence in the first GNSS fence and reaches the third fence in the second GNSS fence. If within the range of the fence, the first virtual card will be activated.

In another possible implementation manner, referring to FIG. 12 , the virtual card switching apparatus 1200 may further include: a determining module 1205 . The determining module 1205 may be configured to detect that the position of the electronic device is within the range of the first fence in the first GNSS fence and within the range of the third fence in the second GNSS fence, or monitor When the position of the electronic device reaches the range of the second fence in the first GNSS fence, and reaches the range of the fourth fence of the second GNSS fence, determine the first virtual The priority of the card is higher than the priority of the second virtual card. The activation module 1204 is specifically configured to activate the first virtual card.

In another possible implementation manner, the acquiring module 1201 is further configured to acquire a movement trend of the electronic device. The activation module 1204 is further configured to activate the virtual card corresponding to the GNSS fence on the mobile trend.

With reference to the second aspect, in another possible implementation manner, the preset length is 1 kilometer; N is 5; or, the GNSS accuracy of N times is greater than 50 meters and less than 500 meters.

With reference to the second aspect, in another possible implementation manner, the GNSS includes the global satellite positioning system GPS, the global navigation satellite system GLONASS, the Beidou satellite navigation system BDS, the quasi-zenith satellite system QZSS or the satellite-based augmentation system SBAS.

It should be understood that the division of units or modules (hereinafter referred to as units) in the above device is only a division of logical functions, and may be fully or partially integrated into a physical entity or physically separated during actual implementation. And the units in the device can all be implemented in the form of software called by the processing element; they can also be implemented in the form of hardware; some units can also be implemented in the form of software called by the processing element, and some units can be implemented in the form of hardware.

For example, each unit can be a separate processing element, or it can be integrated in a certain chip of the device. In addition, it can also be stored in the memory in the form of a program, which is called and executed by a certain processing element of the device. Function. In addition, all or part of these units can be integrated together, or implemented independently. The processing element described here may also be referred to as a processor, and may be an integrated circuit with a signal processing capability. In the process of implementation, each step of the above method or each unit above may be implemented by an integrated logic circuit of hardware in the processor element or implemented in the form of software called by the processing element.

In one example, the units in the above device may be one or more integrated circuits configured to implement the above method, for example: one or more ASICs, or, one or more DSPs, or, one or more FPGAs, Or a combination of at least two of these integrated circuit forms.

For another example, when the units in the device can be implemented in the form of a processing element scheduler, the processing element can be a general-purpose processor, such as a CPU or other processors that can call programs. For another example, these units can be integrated together and implemented in the form of a system-on-a-chip (SOC).

In one implementation, the units of the above apparatus for implementing each corresponding step in the above method may be implemented in the form of a processing element scheduler. For example, the apparatus may include a processing element and a storage element, and the processing element invokes a program stored in the storage element to execute the methods described in the above method embodiments. The storage element may be a storage element on the same chip as the processing element, that is, an on-chip storage element.

In another implementation, the program for executing the above method may be stored in a storage element on a different chip from the processing element, that is, an off-chip storage element. At this point, the processing element invokes or loads a program from the off-chip storage element to the on-chip storage element, so as to invoke and execute the methods described in the above method embodiments.

For example, an embodiment of the present application may also provide an apparatus, such as an electronic device, which may include a processor, and a memory configured to store instructions executable by the processor. When the processor is configured to execute the above instructions, the electronic device implements the virtual card switching method as described in the foregoing embodiments. The memory can be located inside the electronic device or outside the electronic device. And the processor includes one or more.

In yet another implementation, the unit of the apparatus that implements each step in the above method may be configured as one or more processing elements, and these processing elements may be set on the corresponding electronic equipment described above, where the processing elements may be integrated circuits , for example: one or more ASICs, or one or more DSPs, or one or more FPGAs, or a combination of these types of integrated circuits. These integrated circuits can be integrated together to form a chip.

For example, an embodiment of the present application further provides a chip, and the chip can be applied to the above-mentioned electronic device. The chip includes one or more interface circuits and one or more processors; the interface circuits and processors are interconnected through lines; the processor receives and executes computer instructions from the memory of the electronic device through the interface circuits, so as to implement the method described in the above embodiment Methods.

An embodiment of the present application further provides a computer program product, including computer instructions for running the above-mentioned electronic device.

Through the description of the above embodiments, those skilled in the art can clearly understand that for the convenience and brevity of the description, only the division of the above-mentioned functional modules is used as an example for illustration. In practical applications, the above-mentioned functions can be allocated according to needs It is completed by different functional modules, that is, the internal structure of the device is divided into different functional modules to complete all or part of the functions described above.

In the several embodiments provided in this application, it should be understood that the disclosed devices and methods may be implemented in other ways. For example, the device embodiments described above are only illustrative. For example, the division of the modules or units is only a logical function division. In actual implementation, there may be other division methods. For example, multiple units or components can be Incorporation or may be integrated into another device, or some features may be omitted, or not implemented. In another point, the mutual coupling or direct coupling or communication connection shown or discussed may be through some interfaces, and the indirect coupling or communication connection of devices or units may be in electrical, mechanical or other forms.

The unit described as a separate component may or may not be physically separated, and the component displayed as a unit may be one physical unit or multiple physical units, that is, it may be located in one place, or may be distributed to multiple different places . Part or all of the units can be selected according to actual needs to achieve the purpose of the solution of this embodiment.

In addition, each functional unit in each embodiment of the present application may be integrated into one processing unit, each unit may exist separately physically, or two or more units may be integrated into one unit. The above-mentioned integrated units can be implemented in the form of hardware or in the form of software functional units.

If the integrated unit is realized in the form of a software function unit and sold or used as an independent product, it can be stored in a readable storage medium. Based on such an understanding, the essence of the technical solutions of the embodiments of the present application or the part that contributes to the prior art, or all or part of the technical solutions can be embodied in the form of software products, such as programs. The software product is stored in a program product, such as a computer-readable storage medium, and includes several instructions to make a device (which may be a single-chip microcomputer, a chip, etc.) or a processor (processor) execute all of the methods described in various embodiments of the present application. or partial steps. The aforementioned storage medium includes: various media capable of storing program codes such as U disk, mobile hard disk, ROM, RAM, magnetic disk or optical disk.

For example, the embodiments of the present application may also provide a computer-readable storage medium on which computer program instructions are stored. When the computer program instructions are executed by the electronic device, the electronic device is made to implement the virtual card switching method described in the foregoing method embodiments.

The above is only a specific implementation of the application, but the protection scope of the application is not limited thereto, and any changes or replacements within the technical scope disclosed in the application should be covered within the protection scope of the application . Therefore, the protection scope of the present application should be determined by the protection scope of the claims.

Claims (20)

1. A virtual card switching method, characterized in that it is applied to an electronic device, the electronic device has a near-field communication NFC function, the electronic device includes a plurality of virtual cards, and the method includes:

   When the electronic device uses the first virtual card to complete data interaction for the first time at the first card swiping point, the electronic device acquires the GNSS position information and GNSS accuracy of the electronic device; the first virtual card being a virtual card in the plurality of virtual cards;

   The electronic device establishes and stores a first GNSS fence corresponding to the first virtual card according to the GNSS position information and the GNSS accuracy, the first GNSS fence includes a first fence and a second fence, the the extent of the first fence is greater than the extent of the second fence;

   When the electronic device monitors that the position of the electronic device reaches the range of the first GNSS fence, the electronic device activates the first virtual card.
2. The method according to claim 1, wherein the first fence is a circular area with the GNSS position information as the center and a preset length as the radius;

   The second fence is a circular area with the GNSS position information as the center and N times the GNSS accuracy as the radius; N is an integer greater than zero, and the preset length is greater than N times the GNSS accuracy .
3. The method according to claim 1, wherein the electronic device also establishes and stores GNSS fences of other virtual cards in the plurality of virtual cards except the first virtual card;

   Wherein, the GNSS fence of the other virtual cards includes: the second GNSS fence corresponding to the second virtual card, the second GNSS fence includes a third fence and a fourth fence, and the range of the third fence is larger than the first fence. Four fenced range.
4. The method according to claim 3, wherein when the electronic device detects that the position of the electronic device is within the range of the first GNSS fence, the electronic device sets the first virtual Card activation, including:

   When the electronic device monitors that the position of the electronic device reaches the range of the first GNSS fence and does not reach the range of the GNSS fences of other virtual cards, the electronic device sets the first virtual The card is activated.
5. The method according to claim 3, wherein when the electronic device detects that the position of the electronic device is within the range of the first GNSS fence, the electronic device sets the first virtual Card activation, including:

   When the electronic device monitors that the position of the electronic device is within the range of the second fence in the first GNSS fence, and within the range of the third fence in the second GNSS fence In some cases, the electronic device activates the first virtual card.
6. The method according to claim 3, wherein when the electronic device detects that the position of the electronic device is within the range of the first GNSS fence, the electronic device sets the first virtual Card activation, including:

   When the electronic device monitors that the position of the electronic device reaches within the range of the first fence in the first GNSS fence and reaches within the range of the third fence in the second GNSS fence, Or, when it is detected that the position of the electronic device reaches within the range of the second fence in the first GNSS fence, and arrives within the range of the fourth fence in the second GNSS fence, The electronic device determines that the priority of the first virtual card is higher than the priority of the second virtual card;

   The electronic device activates the first virtual card.
7. The method according to claim 6, further comprising:

   In the case that the priority of the first virtual card is the same as that of the second virtual card, the electronic device acquires a movement trend of the electronic device;

   The electronic device activates the virtual card corresponding to the GNSS fence on the moving trend.
8. The method according to any one of claims 1-7, wherein the first virtual card is specifically a virtual card of a predetermined type among the plurality of virtual cards.
9. The method according to claim 2, wherein the preset length is 1 kilometer;

   The N is 5; or, the GNSS accuracy of the N times is greater than 50 meters and less than 500 meters.
10. The method according to any one of claims 1-7, wherein the GNSS includes Global Positioning System GPS, Global Navigation Satellite System GLONASS, Beidou Satellite Navigation System BDS, Quasi-Zenith Satellite System QZSS or satellite-based Enhanced system SBAS.
11. A virtual card switching method, characterized in that it is applied to an electronic device, the electronic device has a near-field communication NFC function, the electronic device includes a plurality of virtual cards, and the method includes:

    When the electronic device uses the first virtual card to complete data interaction for the first time at the first card swiping point, the electronic device acquires the GNSS position information and GNSS accuracy of the electronic device; the first virtual card being a virtual card in the plurality of virtual cards;

    The electronic device establishes and stores a first GNSS fence corresponding to the first virtual card according to the GNSS position information and the GNSS accuracy, the first GNSS fence includes a first fence and a second fence, the The range of the first fence is larger than the range of the second fence; the electronic device also establishes and stores the GNSS fences of other virtual cards in the plurality of virtual cards except the first virtual card; wherein, the The GNSS fences of other virtual cards include: the second GNSS fence corresponding to the second virtual card, the second GNSS fence includes a third fence and a fourth fence, and the scope of the third fence is greater than the scope of the fourth fence ;

    When the electronic device monitors that the position of the electronic device reaches the range of the first GNSS fence, the electronic device activates the first virtual card, including:

    When the electronic device monitors that the position of the electronic device reaches within the range of the first fence in the first GNSS fence and reaches within the range of the third fence in the second GNSS fence, Or, when it is detected that the position of the electronic device reaches within the range of the second fence in the first GNSS fence, and arrives within the range of the fourth fence in the second GNSS fence, The electronic device determines that the priority of the first virtual card is higher than the priority of the second virtual card;

    The electronic device activates the first virtual card.
12. The method according to claim 11, wherein the first fence is a circular area with the GNSS position information as the center and a preset length as the radius;

    The second fence is a circular area with the GNSS position information as the center and N times the GNSS accuracy as the radius; N is an integer greater than zero, and the preset length is greater than N times the GNSS accuracy .
13. The method according to claim 11, wherein when the electronic device detects that the position of the electronic device is within the range of the first GNSS fence, the electronic device sets the first virtual Card activation, also includes:

    When the electronic device monitors that the position of the electronic device reaches the range of the first GNSS fence and does not reach the range of the GNSS fences of other virtual cards, the electronic device sets the first virtual The card is activated.
14. The method according to claim 11, wherein when the electronic device detects that the position of the electronic device is within the range of the first GNSS fence, the electronic device sets the first virtual Card activation, also includes:

    When the electronic device monitors that the position of the electronic device is within the range of the second fence in the first GNSS fence, and within the range of the third fence in the second GNSS fence In some cases, the electronic device activates the first virtual card.
15. The method according to claim 11, characterized in that the method further comprises:

    In the case that the priority of the first virtual card is the same as that of the second virtual card, the electronic device acquires a movement trend of the electronic device;

    The electronic device activates the virtual card corresponding to the GNSS fence on the moving trend.
16. The method according to any one of claims 11-15, wherein the first virtual card is specifically a virtual card of a predetermined type among the plurality of virtual cards.
17. The method according to claim 15, wherein the preset length is 1 kilometer;

    The N is 5; or, the GNSS accuracy of the N times is greater than 50 meters and less than 500 meters.
18. The method according to any one of claims 11-15, wherein the GNSS includes Global Positioning System GPS, Global Navigation Satellite System GLONASS, Beidou Satellite Navigation System BDS, Quasi-Zenith Satellite System QZSS or satellite-based Enhanced system SBAS.
19. An electronic device, characterized in that the electronic device includes a processor, a memory for storing instructions executable by the processor; when the processor is configured to execute the instructions, the electronic device implements the following: A method as claimed in any one of claims 1 to 10.
20. A computer-readable storage medium on which computer program instructions are stored; it is characterized in that,

    When the computer program instructions are executed by the electronic device, the electronic device is made to implement the method according to any one of claims 1 to 10.

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