CN113055979A - Network residing method, wearable device, communication card assembly and readable storage medium - Google Patents

Abstract

The application relates to a network residing method, a wearable device, a communication card assembly and a readable storage medium, wherein the method comprises the following steps: the first processor receives user identification card information sent by the second processor, wherein the user identification card information is received by the second processor from the communication card assembly; the first processor generates a network residing request corresponding to the user identification card information; the first processor sends the network residing request to network access equipment through the first radio frequency module, wherein the network residing request is used for indicating the network access equipment to complete network residing of the user identity identification card. By adopting the method, the power consumption can be reduced.

Description

Network residing method, wearable device, communication card assembly and readable storage medium

Technical Field

The present application relates to the field of communications technologies, and in particular, to a network residence method, a wearable device, a communication card assembly, and a computer-readable storage medium.

Background

With the development of science and technology, the use of electronic equipment is more and more popular. The conventional network residence mode is that each electronic device is connected with a base station to conduct network residence. However, the conventional network-resident method has a problem of large power consumption.

Disclosure of Invention

The embodiment of the application provides a network residing method, a network residing device, wearable equipment and a computer readable storage medium, and power consumption can be reduced.

A network residing method is applied to wearable equipment, wherein the wearable equipment comprises a first processor, a second processor and a first radio frequency module, the first processor is connected with the first radio frequency module, the second processor is used for communicating with a communication card assembly, and the communication card assembly comprises a user identity identification card; the network residing method comprises the following steps:

the first processor receives the user identification card information sent by the second processor, and the user identification card information is received by the second processor from the communication card assembly;

the first processor generates a network residing request corresponding to the information of the user identity identification card;

the first processor sends a network residing request to the network access equipment through the first radio frequency module, and the network residing request is used for indicating the network access equipment to complete network residing on the user identity identification card.

A network residing method is applied to a communication card assembly, the communication card assembly comprises a user identity identification card, the communication card assembly is communicated with wearable equipment, and the method comprises the following steps:

acquiring user identity identification card information;

sending user identity identification card information to the wearable device, wherein the user identity identification card information is used for indicating the wearable device to receive the user identity identification card information through the second processor, sending the user identity identification card information to the first processor, and generating a network parking request corresponding to the user identity identification card information through the first processor; and sending a network residing request to the network access equipment through the first processor, wherein the network residing request is used for indicating the network access equipment to complete network residing of the user identity identification card.

A wearable device comprises a first processor, a second processor and a first radio frequency module, wherein the first processor is connected with the first radio frequency module, and the second processor is used for communicating with a communication card component; the first processor is used for receiving the user identification card information sent by the second processor, and the user identification card information is received by the second processor from the communication card assembly;

the first processor is used for generating a network residing request corresponding to the information of the user identity identification card;

the first processor is used for sending a network residing request to the network access equipment through the first radio frequency module, and the network residing request is used for indicating the network access equipment to complete network residing on the user identity identification card. A communication card assembly comprises a card reading module, a user identification card and a communication module, wherein the card reading module is respectively connected with the user identification card and the communication module;

the card reading module is used for reading the user identification card to obtain the information of the user identification card and sending the information of the user identification card to the communication module;

the communication module is used for sending user identity identification card information to the wearable device, the user identity identification card information is used for indicating the wearable device to receive the user identity identification card information through the second processor, the user identity identification card information is sent to the first processor, and a network parking request corresponding to the user identity identification card information is generated through the first processor; and sending a network residing request to the network access equipment through the first processor, wherein the network residing request is used for indicating the network access equipment to complete network residing of the user identity identification card.

A computer-readable storage medium, on which a computer program is stored which, when executed by a processor, carries out the steps of:

the first processor receives the user identification card information sent by the second processor, and the user identification card information is received by the second processor from the communication card assembly;

the first processor generates a network residing request corresponding to the information of the user identity identification card;

the first processor sends a network residing request to the network access equipment through the first radio frequency module, and the network residing request is used for indicating the network access equipment to complete network residing on the user identity identification card.

A computer-readable storage medium, on which a computer program is stored which, when executed by a processor, carries out the steps of:

acquiring user identity identification card information;

sending user identity identification card information to the wearable device, wherein the user identity identification card information is used for indicating the wearable device to receive the user identity identification card information through the second processor, sending the user identity identification card information to the first processor, and generating a network parking request corresponding to the user identity identification card information through the first processor; and sending a network residing request to the network access equipment through the first processor, wherein the network residing request is used for indicating the network access equipment to complete network residing of the user identity identification card.

According to the network residing method, the wearable device, the communication card assembly and the computer readable storage medium, the first processor receives the user identity identification card information sent by the second processor, the user identity identification card information is received by the second processor from the communication card assembly, the first processor generates the network residing request corresponding to the user identity identification card information, the network residing request is sent to the network access device through the first processor, the network access device can complete the network residing of the user identity identification card under the condition of double processors, the communication card assembly is decoupled with the wearable device, the user identity identification card of the wearable device can be conveniently replaced, the communication card assembly performs the network residing through the wearable device, the wearable device can achieve the functions of communication, internet surfing and the like through the user identity identification card, and the electric quantity of the communication card assembly can be saved.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a diagram of an application environment for a web-hosting method in one embodiment;

FIG. 2 is a diagram of a hardware architecture for a web hosting method in one embodiment;

FIG. 3 is a block diagram of an embodiment of a SIM card;

FIG. 4 is a flow diagram of a web hosting method in one embodiment;

fig. 5 is a schematic structural diagram of an eSIM card in an embodiment;

FIG. 6 is a timing diagram of a web hosting method in one embodiment;

FIG. 7 is a diagram of an application environment for multiple card and multiple standby in one embodiment;

FIG. 8 is a schematic diagram of an application environment in which the communication card assembly communicates with the wearable device in the embodiment;

FIG. 9 is a diagram of an application environment for the web-hosting method in another embodiment;

FIG. 10 is a flowchart illustrating a web hosting method according to yet another embodiment;

fig. 11 is a schematic diagram of the internal structure of the wearable device in one embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

It will be understood that, as used herein, the terms "first," "second," and the like may be used herein to describe various elements, but these elements are not limited by these terms. These terms are only used to distinguish one element from another. For example, a first processor may be referred to as a second processor, and similarly, a second processor may be referred to as a first processor, without departing from the scope of the present application. The first processor and the second processor are both processors, but they are not the same processor.

FIG. 1 is a diagram of an application environment of the web-hosting method in one embodiment. Including wearable device 110, communication card component 120, and network access device 130. Wherein the wearable device 110 is in communication with the communication card component 120. Wearable device 110 may be connected to network access device 130 via a network, thereby implementing a network residence. The wearable device 110 may be a watch, a bracelet, glasses, or other electronic devices. The communication card assembly 120 has a user identification card and a communication module for communicating with the wearable device 110. Network access device 130 may be a base station or the like.

FIG. 2 is a diagram of a hardware architecture of a web hosting method in one embodiment. Wearable device 110 includes a first radio frequency module 112, a first processor 114, a second processor 116, and a first communication module 118. The first processor 114 is connected to the first rf module 112. The second processor 116 can communicate with the Communication card assembly 120 through bluetooth, wifi, FM signal, NFC (Near Field Communication) module, and the like. The first processor 114 and the second processor 116 are both microprocessors, wherein the first processor 114 may be a core processor. The first processor 114 and the second processor 116 may configure corresponding microprocessors according to actual applications, and the first processor 114 and the second processor 116 are not limited herein. The System may be, but is not limited to, an android System, a Linux System, a Windows System, an IOS System, an RTOS (Real Time Operating System), and the like. And the first processor 114 may have a higher power consumption for the first system than the second processor 116 for the second system. For example, the first processor 114 may be a Central Processing Unit (CPU) processor, and the corresponding first system may be an Android system; the second processor 116 may be an MCU (micro controller Unit) processor, and the corresponding second system may be an RTOS. The CPU has a main frequency up to 1.2GHz (gigahertz), and the MCU has a main frequency of about 120MHz (megahertz), so that the power consumption of the first processor is higher than that of the second processor, and the power consumption of the first system is higher than that of the second system. The first processor 114 and the second processor 116 are connected through an SPI (Serial Peripheral Interface), so that the first system and the second system can transmit communication data through the SPI bus. The communication card assembly 120 includes a user identification card 124 and a second communication module 122 that communicates with the wearable device. The second communication module 122 may specifically be at least one of a bluetooth module, a WIFI module, an NFC module, and a radio frequency module, but is not limited thereto.

FIG. 3 is a block diagram of an embodiment of a SIM card. As shown in fig. 3, the user id card 124 includes 6 ISO7816 interfaces. The ISO7816 transmission protocol is used for transmitting information between the wearable device and the user identification card. In fig. 3, VCC is a power supply voltage, RESET is a RESET signal, CLK is a clock signal, GND is ground, VPP is a programming voltage, and IO is an input/output interface.

FIG. 4 is a flow diagram of a web hosting method in one embodiment. The network-resident method in this embodiment is described by taking the wearable device 110 as an example. As shown in fig. 4, the network residence method is applied to a wearable device, where the wearable device includes a first processor and a second processor, where the first processor is connected to a first radio frequency module, the second processor is used to communicate with a communication card assembly, and the communication card assembly includes a user identification card, including steps 402 to 408.

In step 402, the first processor receives the user identification card information sent by the second processor, where the user identification card information is received by the second processor from the communication card assembly.

The communication card assembly comprises a user identity identification card and a communication module. Wherein, the communication module can only be used for communicating with the wearable device, namely the communication module can not be used for staying the net. The communication module can be used for completing the network residence of the user identification card. A Subscriber Identity Module (SIM) card may be used to access the network. The Subscriber identity card information may include an ICCID (integrated circuit card identity), an IMSI (International Mobile Subscriber identity Number), a KI (Key identity), and the like. The ICCID is the identity of the card and the IMSI is the identity of the subscriber. The ICCID is used only to distinguish the SIM card and is not used for authentication of the access network. The IMSI is authenticated in the server of the operator when accessing the network. The KI is a key preset in the card by the operator, and generally, the key cannot be directly read by the user, and authentication verification is performed by matching with the IMSI when the user registers the network. The encryption data and algorithm of the operator are preset in the user identification card.

Specifically, an eSIM (Embedded-SIM) card may be included in the wearable device. Fig. 5 is a schematic structural diagram of an eSIM card in an embodiment. The port C1 can be power voltage, the port C2 is reset signal, the port C3 is clock signal, the port C5 is ground, the port C6 is not used, the port C7 is input/output interface, etc. Since the eSIM card is difficult to detach, the communication card components can be configured independently. The communication card assembly acquires the information of the user identification card and sends the information of the user identification card to the wearable device. The wearable device receives the user identification card information sent by the communication card component through the second processor connected with the communication module. The first processor and the second processor may be connected through the SPI. The second processor may be used to implement some of the basic functions of the wearable device. Such as a clock function, heart rate detection function, motion related function, etc. And the second processor of the wearable device sends the user identification card information to the first processor.

In step 404, the first processor generates a network residing request corresponding to the user identification card information.

And the network residing request is used for completing the network residing of the user identity identification card. The network-residing request comprises the information of the user identification card.

Specifically, the wearable device uses the radio frequency module to communicate with the network access device, and simultaneously needs to be connected with the user identification card in real time to perform handshake authentication. The wearable device and the user identification card are usually completed through physical connection based on an ISO7816 transmission protocol. The wearable device generates a network-residing request containing the information of the user identification card in the first processor according to the information of the user identification card. The wearable device can acquire the KI and the IMSI and generate a network residing request.

Step 406, the first processor sends a network-residing request to the network access device through the first radio frequency module, where the network-residing request is used to instruct the network access device to complete network-residing of the user identification card.

Specifically, the wearable device sends a network-residing request to the network access device through the first processor. And the network access equipment identifies whether the user identification card has the authority to carry out network residence according to the information of the user identification card. And when the network access equipment determines that the user identification card information has the authority to carry out network residence, completing the network residence of the user identification card.

In the network residence method in this embodiment, the first processor receives the user identification card information sent by the second processor, the user identification card information is received by the second processor from the communication card component, the first processor generates a network residence request corresponding to the user identification card information, the first processor sends the network residence request to the network access device through the first radio frequency module, the network access device can complete the network residence of the user identification card under the condition of dual processors, the communication card component is decoupled from the wearable device, the user identification card of the wearable device is convenient to replace, the communication card component performs network residence through the wearable device, the wearable device can use the user identification card to realize functions of communication, internet surfing and the like, and the electric quantity of the communication card component can be saved.

In one embodiment, as shown in FIG. 6, a timing diagram of a web hosting method in one embodiment is shown. The method for sending a network residing request to a network access device through a first processor, wherein the network residing request is used for indicating the network access device to complete network residing of a user identification card, and comprises the following steps:

step 602, a network residence request is sent to a network access device through a first processor.

Step 604, receiving, by the first processor, an authentication request generated by the network access device according to the network camping request.

Specifically, the network access device initiates an authentication procedure to determine whether the subscriber identity card is camping on the network.

Step 606, the authentication request is sent to the second processor.

Specifically, the first processor sends an authentication request to the second processor.

Step 608, sending, by the second processor, an authentication request to the communication card component.

And step 610, receiving an authentication result sent by the communication card assembly through the second processor, wherein the authentication result is obtained by the communication card assembly performing authentication on the user identity identification card according to the authentication request.

Step 612, the authentication result is sent to the first processor.

And 614, sending an authentication result to the network access equipment through the first processor, wherein the authentication result is used for indicating the network access equipment to finish the network residence of the user identity identification card.

In the network residence method in this embodiment, a network residence request is sent to a network access device through a first processor, an authentication request generated by the network access device according to the network residence request is received through the first processor, the authentication request is sent to a second processor, the authentication request is sent to a communication card component through the second processor, the authentication result is sent to the first processor, the authentication result is sent to the network access device through the first processor, the authentication result is used for indicating the network access device to complete network residence of a user identity identification card, and the communication card component is decoupled from a wearable device, so that the user identity identification card of the wearable device can be conveniently replaced, the communication card component conducts network residence through the wearable device, the wearable device can use the user identity identification card to realize functions of conversation, internet surfing and the like, and the electric quantity of the communication card component can be saved.

In one embodiment, the number of communication card components is at least two. And receiving the user identification card information sent by each communication card component in the at least two communication card components through the second processor to obtain at least two user identification card information. The first processor receives the user identification card information sent by the second processor, and the method comprises the following steps: the first processor receives at least two kinds of user identification card information sent by the second processor. The first processor generates a network residing request corresponding to the information of the user identification card, and comprises the following steps: the first processor generates a network residing request corresponding to each type of user identification card information.

Specifically, as shown in fig. 7, it is a diagram of an application environment with multiple cards and multiple standby in one embodiment. As shown in fig. 7, the wearable device 710 may communicate through a radio frequency module network access device. The wearable device 710 can establish communication connection with the communication card assembly a720, the communication card assembly B730 … and the communication card assembly N740 through the communication module. The wearable device can realize the network-resident connection of the communication component A and the communication component B …. The wearable device can establish communication connection with at least two communication card components, thereby realizing multi-card multi-standby. The wearable device receives the user identification card information sent by each communication card component in the at least two communication card components through the second processor to obtain at least two types of user identification card information, and sends the at least two types of user identification card information to the first processor. The wearable device generates a network residing request corresponding to each of the at least two types of user identification card information through the first processor. For example, the user identification card information A, the network-residing request is a; the user identification card information is B, and the network-residing request is B. The wearable device may in turn send a network-resident request to the network access device. Or, the wearable device may encapsulate the network residence request into a network residence request set through the first processor, and send the network residence request set to the network access device.

In this embodiment, the wearable device may encapsulate at least two types of user identification card information into a user identification card information set through the second processor, and send the user identification card information set to the first processor.

In the network residence method in this embodiment, the second processor receives the user identification card information sent by each of the at least two communication card assemblies to obtain at least two types of user identification card information, the first processor receives the at least two types of user identification card information sent by the second processor, and the first processor generates a network residence request corresponding to each type of user identification card information, so that a plurality of user identification cards can be connected with the wearable device, and multi-card multi-standby is realized.

In one embodiment, each communication card component has a corresponding receive frequency and transmit frequency; each communication card component adopts corresponding receiving frequency and sending frequency to communicate with the wearable device.

Specifically, the first communication module and the second communication module may be radio Frequency modules, and are configured to transmit FM (Frequency Modulation) signals. Then, each of the at least two communication card components has a corresponding reception frequency and transmission frequency. For example, the communication card component a corresponds to a receiving frequency α and a transmitting frequency β; the receiving frequency corresponding to the communication card component B is epsilon, and the corresponding sending frequency is eta. Wherein the frequency values of α, β, ε, and η are different. Each communication card component adopts corresponding receiving frequency and sending frequency to communicate with the wearable device. Fig. 8 is a schematic diagram of an application environment in which the communication card component communicates with the wearable device in the embodiment. For example, the wearable device 810 transmits data to the communication card assembly a at the transmission frequency α, and receives data transmitted by the communication card assembly a at the reception frequency β.

In the network residence method in this embodiment, each communication card component has a corresponding receiving frequency and a corresponding sending frequency, and each communication card component communicates with the wearable device by using the corresponding receiving frequency and the corresponding sending frequency, and can realize communication connection by using FM signals, thereby realizing multi-card multi-standby.

In one embodiment, before sending the subscriber identity card information to the first processor, the network-hosting method further comprises: when the wearable device is detected to be in the power saving mode, a first system corresponding to the first processor is closed, and the second processor is connected with the communication card assembly; and when the wearable device is switched from the power saving mode to the normal use mode, starting the first system, and executing the step that the first processor receives the information of the user identity identification card sent by the second processor.

In particular, since the power consumption of the first system is higher than the power consumption of the second system. The wearable device closes the first system corresponding to the first processor, namely the wearable device cannot be on the internet at this time. And when the wearable device is detected to be in the power saving mode, controlling a switch in the wearable device to switch from a path of the first processor and other devices to a path of other devices of the second processor, and closing the first system, wherein the second processor is still in communication connection with the communication card assembly. Then, when the wearable device is switched from the power saving mode to the normal use mode, the first system is started, and at this time, the wearable device can directly send the user identification card information in the second processor to the first processor, that is, the first processor directly receives the user identification card information sent by the second processor, and communication connection does not need to be performed again.

In the network-residing method in this embodiment, when it is detected that the wearable device is in the power saving mode, the first system corresponding to the first processor is turned off, and the second processor is connected with the communication card component; when the wearable device is switched to a normal use mode from a power saving mode, the first system is started, the step that the first processor receives the information of the user identification card sent by the second processor is executed, the first processor can be still connected with the communication card assembly even under the condition of the power saving mode, namely under the condition that the first system is closed, and the first processor can rapidly receive the information of the user identification card from the second processor when the first system is electrified, so that the network residence time is shortened, and the network residence efficiency is improved.

In one embodiment, before sending the subscriber identity card information to the first processor, the network-hosting method further comprises: when detecting that the wearable device cannot be parked in the network, the second processor is still connected with the communication card component; and when the wearable device can be in a network, executing the step that the first processor receives the user identification card information sent by the second processor. Specifically, the wearable device being unable to camp on the network may be that the wearable device is in an environment with weak signals, and therefore unable to camp on the network. Or, the wearable device is in a power saving mode, and the first system is turned off, so that the wearable device cannot stay on the network. When the wearable device can be in a network, the first processor can rapidly receive the information of the user identification card from the second processor, so that the network-in time is shortened, and the network-in efficiency is improved.

In one embodiment, the subscriber identity card information includes an international mobile subscriber identity and an integrated circuit card identification. After sending the subscriber identity card information to the first processor, the network-residing method further comprises: and when the first processor detects that the international mobile subscriber identity and the integrated circuit card identity are bound with the wearable device, executing a step of generating a network-residing request corresponding to the subscriber identity card information by the first processor.

Specifically, before the user identification card information sent by the communication card component is received by the second processor, the communication card component and the wearable device are bound. The International Mobile Subscriber Identity (IMSI) and the Integrated Circuit Card Identity (ICCID) of the user identity card are pre-bound with the wearable device in advance, and only the bound communication card component is allowed to realize network residence through the wearable device. After the user identification card information is sent to the first processor, when the first processor detects that the international mobile user and the integrated circuit card identification code are bound with the wearable device, a network-residing request corresponding to the user identification card information is generated through the first processor.

In the network residence method in this embodiment, when it is detected by the first processor that the international mobile subscriber identity and the integrated circuit card identity are bound to the wearable device, a step of generating a network residence request corresponding to the subscriber identity card information by the first processor is performed, so that network residence can be performed for the bound subscriber identity card, and network residence cannot be performed for an unbound subscriber identity card.

In one embodiment, the wearable device may also include a user identification card, in this embodiment, the user identification card in the communication card assembly is referred to as a first user identification card, and the user identification card in the wearable device is referred to as a second user identification card. The network residing method further comprises the following steps: and acquiring the information of the second user identification card through the first processor, and generating a second network residing request corresponding to the information of the second user identification card. And sending a second network-residing request to the network access equipment through the first processor, wherein the second network-residing request is used for indicating the network access equipment to complete network residing on the second subscriber identity identification card. The network residence method in the embodiment can realize the network residence of the second user identity identification card in the wearable device.

In one embodiment, a web hosting method is applied to a wearable device, and includes:

step a1, when detecting that the wearable device is in the power saving mode, closing the first system corresponding to the first processor, and keeping the second processor connected with the communication card component.

Step a2, when the wearable device switches from the power saving mode to the normal use mode, the first system is turned on, the first processor receives the user identification card information sent by the second processor, and the user identification card information is received by the second processor from the communication card assembly.

Step a3, when detecting that the international mobile subscriber identity and the integrated circuit card identity are bound to the wearable device, the first processor generates a network-resident request corresponding to the subscriber identity card information, wherein the subscriber identity card information includes the international mobile subscriber identity and the integrated circuit card identity.

In step a4, the first processor sends a network residing request to the network access device and sends an authentication request to the communication card assembly through the second processor.

In step a5, the first processor receives the authentication result sent by the second processor in fig. 11, and the authentication result in fig. 11 is received by the second processor in fig. 11 from the communication card assembly in fig. 11, where the authentication result in fig. 11 is obtained by the communication card assembly in fig. 11 performing authentication on the user identification card according to the authentication request in fig. 11.

Step a6, the first processor sends the authentication result of fig. 11 to the network access device of fig. 11 through the first rf module of fig. 11, where the authentication result of fig. 11 is used to instruct the network access device of fig. 11 to complete network residence on the user identification card of fig. 11.

The network residence method in the embodiment can ensure that the first processor can still be connected with the communication card assembly even under the condition of a power-saving mode, namely under the condition that the first system is closed, and can quickly receive the information of the user identity identification card from the second processor when the first system is powered on, thereby reducing the network residence time and improving the network residence efficiency; can make network access equipment accomplish the staying net to user identification card under the condition of dual processor to communication card subassembly and wearable equipment decoupling zero conveniently change the user identification card of wearable equipment, and the communication card subassembly stays net through wearable equipment, and wearable equipment can use user identification card to realize functions such as conversation, surfing the net, also can save the electric quantity of communication card subassembly.

In one embodiment, as shown in FIG. 9, a diagram of an application environment for a web-hosting method in another embodiment is shown. The wearable device 910 may include a radio frequency module, an ISO7816 card reading module, a first bluetooth module, and a first user identification card. The radio frequency module, the first Bluetooth module and the first user identity identification card module are respectively connected with the ISO7816 card reading module. The communication card assembly 920 comprises a second user identification card, an ISO7816 card reading module and a second Bluetooth module. The communication card components may be located in other wearable devices than wearable device 910. The second user identification card is connected with the ISO7816 card reading module, and the ISO7816 card reading module is connected with the second Bluetooth module. Besides the communication between the radio frequency module and the operator base station, the wearable device also needs to be connected with the first user identification card in real time to perform handshake authentication. The wearable device and the SIM card are usually completed through physical connection based on an ISO7816 transmission protocol. The user identification card is preset with the encryption data and algorithm of the operator. The communication card assembly 920 can read the information of the second user identification card through the ISO7816 card reading module, the second user identification card information is sent to the first Bluetooth module through the second Bluetooth module, the first Bluetooth module sends the information of the second user identification card to the ISO7816 card reading module, and the ISO7816 card reading module sends the information of the second user identification card to the radio frequency module to complete network parking.

In one embodiment, as shown in fig. 10, a flowchart of a web hosting method in another embodiment is shown. A network residing method is applied to a communication card assembly, the communication card assembly comprises a user identity identification card, the communication card assembly is communicated with wearable equipment, and the network residing method comprises the following steps:

step 1002, obtaining user identification card information;

step 1004, sending user identification card information to the wearable device, wherein the user identification card information is used for indicating the wearable device to receive the user identification card information through the second processor, sending the user identification card information to the first processor, and generating a network residing request corresponding to the user identification card information through the first processor; and sending a network residing request to the network access equipment through the first processor, wherein the network residing request is used for indicating the network access equipment to complete network residing of the user identity identification card.

The network residence method in the embodiment acquires the information of the user identity identification card; sending user identity identification card information to the wearable device, wherein the user identity identification card information is used for indicating the wearable device to receive the user identity identification card information through the second processor, sending the user identity identification card information to the first processor, and generating a network parking request corresponding to the user identity identification card information through the first processor; the network-residing request is sent to the network access equipment through the first processor, the network-residing request is used for indicating the network access equipment to complete network residing of the user identity identification card, network residing of the communication card assembly decoupled with the wearable equipment can be achieved, functions of communication, internet surfing and the like of the wearable equipment can be achieved through the communication card assembly, and meanwhile electric quantity of the communication card assembly is saved.

In one embodiment, the communications card assembly may include a second radio frequency module. The network residing method further comprises the following steps: when the distance between the communication card assembly and the wearable device is detected to be within a preset distance range, closing the radio frequency module, and establishing communication connection with the wearable device; and when the distance between the communication card assembly and the wearable device is detected to exceed the preset distance range, the second radio frequency module is opened, and the network is resident through the second radio frequency module.

Specifically, the communication card subassembly can detect whether the distance with wearing formula equipment is in preset distance range according to signal strength. When the signal intensity of the communication module reaches the signal intensity threshold value, namely the distance between the communication card assembly and the wearable device is within a preset distance range, the second radio frequency module is closed, and communication connection is established with the wearable device. And when the signal intensity of the communication module is detected to be smaller than the signal intensity threshold value, namely the distance between the communication card assembly and the wearable device exceeds a preset distance range, the radio frequency module is opened, and the network is parked through the second radio frequency module.

In the network-resident method in the embodiment, when the distance between the communication card assembly and the wearable device is detected to be within the preset distance range, the radio frequency module is closed, the communication connection is established with the wearable device, and the network-resident standby can be realized through the wearable device, so that the power consumption of the communication card assembly is reduced, and the endurance time of the communication card assembly is prolonged; when the distance between the communication card assembly and the wearable device exceeds the preset distance range, the second radio frequency module is opened, the network is parked through the second radio frequency module, and the network can be parked when the wearable device is far away.

In one embodiment, the communication card assembly includes a second radio frequency module. The network residing method further comprises the following steps: and when the situation that the communication connection with the wearable device cannot be established is detected, the second radio frequency module is used for networking. In the network residence method in this embodiment, when the communication card assembly includes the radio frequency module and detects that the communication connection with the wearable device cannot be established, the network residence is performed through the second radio frequency module, so that the realization of functions such as conversation and the like is not affected.

It should be understood that although the various steps in the flowcharts of fig. 4, 6 and 10 are shown in order as indicated by the arrows, the steps are not necessarily performed in order as indicated by the arrows. The steps are not performed in the exact order shown and described, and may be performed in other orders, unless explicitly stated otherwise. Moreover, at least some of the steps in fig. 4, 6, and 10 may include multiple sub-steps or multiple stages that are not necessarily performed at the same time, but may be performed at different times, and the order of performing the sub-steps or stages is not necessarily sequential, but may be performed alternately or alternatingly with other steps or at least some of the sub-steps or stages of other steps.

In one embodiment, a wearable device, as shown in fig. 2, includes a first processor, a second processor, and a first radio frequency module, the first processor is connected to the first radio frequency module, and the second processor is configured to communicate with a communication card component; the first processor is used for receiving the user identification card information sent by the second processor, and the user identification card information is received by the second processor from the communication card assembly;

the first processor is used for generating a network residing request corresponding to the information of the user identity identification card;

the first processor is used for sending a network residing request to the network access equipment through the first radio frequency module, and the network residing request is used for indicating the network access equipment to complete network residing on the user identity identification card.

The wearable device in this embodiment can make the network access device accomplish the staying of user identification card under the condition of dual processor to the decoupling of communication card subassembly and wearable device, conveniently change the user identification card of wearable device, and the communication card subassembly stays the net through wearable device, and wearable device can use user identification card to realize functions such as conversation, surfing the net, also can save the electric quantity of communication card subassembly.

In one embodiment, the first processor is configured to receive an authentication request generated by the network access device according to the network residing request after the first processor sends the network residing request to the network access device through the first radio frequency module;

the first processor sends the authentication request to the second processor, and sends the authentication request to the communication card assembly through the second processor;

the first processor receives an authentication result sent by the second processor, wherein the authentication result is received by the second processor from the communication card assembly, and the authentication result is obtained by the communication card assembly performing authentication on the user identity identification card according to the authentication request;

the first processor sends an authentication result to the network access equipment through the first radio frequency module, and the authentication result is used for indicating the network access equipment to complete network residence of the user identity identification card.

The wearable device in this embodiment sends a network residing request to the network access device through the first processor, receives an authentication request generated by the network access device according to the network residing request through the first processor, sends the authentication request to the second processor, sends the authentication request to the communication card assembly through the second processor, sends the authentication result to the first processor, sends the authentication result to the network access device through the first processor, the authentication result is used for indicating the network access device to complete network residing of the user identification card, and the communication card assembly is decoupled from the wearable device, so that the user identification card of the wearable device can be conveniently replaced, the communication card assembly performs network residing through the wearable device, the wearable device can use the user identification card to realize functions of conversation, surfing the internet and the like, and the electric quantity of the communication card assembly can be saved.

In one embodiment, the first processor is further configured to, before receiving the user identification card information sent by the second processor, when it is detected that the wearable device is in the power saving mode, turn off a first system corresponding to the first processor; the second processor is connected with the communication card assembly; when the wearable device is switched to a normal use mode from the power saving mode, the first system is started, and the first processor receives the user identity identification card information sent by the second processor.

In the wearable device in this embodiment, when it is detected that the wearable device is in the power saving mode, the first system corresponding to the first processor is turned off, and the second processor is connected to the communication card assembly; when the wearable device is switched to a normal use mode from a power saving mode, the first system is started, the step that the first processor receives the information of the user identification card sent by the second processor is executed, the first processor can be still connected with the communication card assembly even under the condition of the power saving mode, namely under the condition that the first system is closed, and the first processor can rapidly receive the information of the user identification card from the second processor when the first system is electrified, so that the network residence time is shortened, and the network residence efficiency is improved.

In one embodiment, the communication card assembly comprises a card reading module, a user identification card and a communication module, wherein the card reading module is respectively connected with the user identification card and the communication module;

the card reading module is used for reading the user identification card to obtain the information of the user identification card and sending the information of the user identification card to the communication module;

the communication module is used for sending user identity identification card information to the wearable device, the user identity identification card information is used for indicating the wearable device to receive the user identity identification card information through the second processor, the user identity identification card information is sent to the first processor, and a network parking request corresponding to the user identity identification card information is generated through the first processor; and sending a network residing request to the network access equipment through the first processor, wherein the network residing request is used for indicating the network access equipment to complete network residing of the user identity identification card.

The communication card assembly in the embodiment of the application comprises a card reading module, a user identity identification card and a communication module, wherein the card reading module is respectively connected with the user identity identification card and the communication module and is used for reading the user identity identification card, obtaining the information of the user identity identification card and sending the information of the user identity identification card to the communication module; the communication module is used for sending user identity identification card information to the wearable device, the user identity identification card information is used for indicating the wearable device to receive the user identity identification card information through the second processor, the user identity identification card information is sent to the first processor, and a network parking request corresponding to the user identity identification card information is generated through the first processor; the network-residing request is sent to the network access equipment through the first processor, the network-residing request is used for indicating the network access equipment to complete network residing of the user identity identification card, network residing of the communication card assembly decoupled with the wearable electronic equipment can be achieved, functions of communication, internet surfing and the like of the wearable electronic equipment can be achieved through the communication card assembly, and meanwhile electric quantity of the communication card assembly is saved.

In one embodiment, the communications card assembly further comprises a second radio frequency module; the communication card assembly is used for closing the second radio frequency module when detecting that the distance between the communication card assembly and the wearable device is within a preset distance range, and establishing communication connection with the wearable device through the communication module; and when the distance between the wearable device and the wearable device is detected to exceed the preset distance range, the second radio frequency module is opened, and the network is parked through the second radio frequency module.

In the communication card assembly in the embodiment, when the distance between the communication card assembly and the wearable device is detected to be within the preset distance range, the radio frequency module is closed, the communication connection is established with the wearable device, and the network-resident standby can be realized through the wearable device, so that the power consumption of the communication card assembly is reduced, and the endurance time of the communication card assembly is prolonged; when the distance between the communication card assembly and the wearable device exceeds the preset distance range, the second radio frequency module is opened, the network is parked through the second radio frequency module, and the network can be parked when the wearable device is far away.

Fig. 11 is a schematic diagram of the internal structure of the wearable device in one embodiment. As shown in fig. 11, the wearable device includes a processor and a memory connected by a system bus. Wherein, the processor is used for providing calculation and control capability and supporting the operation of the whole wearable device. The memory may include a non-volatile storage medium and an internal memory. The non-volatile storage medium stores an operating system and a computer program. The computer program can be executed by a processor to implement a web hosting method provided in the following embodiments. The internal memory provides a cached execution environment for the operating system computer programs in the non-volatile storage medium. The wearable device can be an electronic device such as a watch, a bracelet, and glasses.

The embodiment of the application also provides a computer readable storage medium. One or more non-transitory computer-readable storage media containing computer-executable instructions that, when executed by one or more processors, cause the processors to perform the steps of the web-hosting method.

A computer program product containing instructions which, when run on a computer, cause the computer to perform a web-hosting method.

Any reference to memory, storage, database, or other medium used herein may include non-volatile and/or volatile memory. Non-volatile memory can include read-only memory (ROM), Programmable ROM (PROM), Electrically Programmable ROM (EPROM), Electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM), which acts as external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms, such as Static RAM (SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), double data rate SDRAM (DDR SDRAM), Enhanced SDRAM (ESDRAM), synchronous Link (Synchlink) DRAM (SLDRAM), Rambus Direct RAM (RDRAM), direct bus dynamic RAM (DRDRAM), and bus dynamic RAM (RDRAM).

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present application. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (14)

1. A network residing method is characterized in that the network residing method is applied to wearable equipment, the wearable equipment comprises a first processor, a second processor and a first radio frequency module, wherein the first processor is connected with the first radio frequency module, the second processor is used for communicating with a communication card assembly, and the communication card assembly comprises a user identity identification card; the method comprises the following steps:

the first processor receives user identification card information sent by the second processor, wherein the user identification card information is received by the second processor from the communication card assembly;

the first processor generates a network residing request corresponding to the user identification card information;

the first processor sends the network residing request to network access equipment through the first radio frequency module, wherein the network residing request is used for indicating the network access equipment to complete network residing of the user identity identification card.

2. The method of claim 1, wherein after the first processor sends the network camping request to a network access device through the first radio frequency module, the method further comprises:

the first processor receives an authentication request generated by the network access equipment according to the network residing request;

the first processor sends the authentication request to the second processor, and sends the authentication request to the communication card assembly through the second processor;

the first processor receives an authentication result sent by the second processor, wherein the authentication result is received by the second processor from the communication card assembly, and the authentication result is obtained by the communication card assembly performing authentication on a user identity identification card according to the authentication request;

the first processor sends the authentication result to the network access equipment through the first radio frequency module, and the authentication result is used for indicating the network access equipment to complete network residence on the user identity identification card.

3. The method according to claim 1 or 2, characterized in that the number of communication card components is at least two;

the second processor receives user identification card information sent by each communication card component in at least two communication card components to obtain at least two types of user identification card information;

the first processor receives the user identification card information sent by the second processor, and the method comprises the following steps:

the first processor receives at least two types of user identification card information sent by the second processor;

the first processor generates a network residing request corresponding to the user identification card information, and the network residing request comprises the following steps:

and the first processor generates a network residing request corresponding to each type of the user identification card information.

4. The method of claim 3, wherein each of the communication card components has a corresponding receive frequency and transmit frequency; each communication card component adopts corresponding receiving frequency and sending frequency to communicate with the wearable device.

5. The method of claim 1, wherein before the first processor receives the subscriber identity card information sent by the second processor, the method further comprises:

when the wearable device is detected to be in a power saving mode, a first system corresponding to the first processor is closed, and the second processor is connected with the communication card assembly;

and when the wearable device is switched from the power saving mode to a normal use mode, starting the first system, and executing the step that the first processor receives the information of the user identity identification card sent by the second processor.

6. The method of claim 1, wherein the subscriber identity card information comprises an international mobile subscriber identity code and an integrated circuit card identity code;

after the first processor receives the subscriber identity module card information sent by the second processor, the method further comprises the following steps:

and when detecting that the international mobile subscriber identity and the integrated circuit card identity are bound with the wearable device, executing a step of generating a network-residing request corresponding to the subscriber identity card information by the first processor.

7. A network residing method is applied to a communication card assembly, the communication card assembly comprises a user identity identification card, the communication card assembly is communicated with wearable equipment, and the method comprises the following steps:

acquiring user identity identification card information;

sending the user identification card information to the wearable device, wherein the user identification card information is used for indicating the wearable device to receive the user identification card information through a second processor, sending the user identification card information to the first processor, and generating a network residing request corresponding to the user identification card information through the first processor; and sending the network residing request to network access equipment through the first processor, wherein the network residing request is used for indicating the network access equipment to complete the network residing of the user identity identification card.

8. The method of claim 7, wherein the communication card assembly includes a second radio frequency module;

the method further comprises the following steps:

when the distance between the communication card assembly and the wearable device is detected to be within a preset distance range, closing the second radio frequency module, and establishing communication connection with the wearable device;

and when the fact that the distance between the communication card assembly and the wearable device exceeds the preset distance range is detected, the second radio frequency module is opened, and network residence is carried out through the second radio frequency module.

9. A wearable device is characterized by comprising a first processor, a second processor and a first radio frequency module, wherein the first processor is connected with the first radio frequency module, and the second processor is used for communicating with a communication card component; the first processor is used for receiving user identification card information sent by the second processor, and the user identification card information is received by the second processor from the communication card assembly;

the first processor is used for generating a network residing request corresponding to the user identification card information;

the first processor is configured to send the network residing request to a network access device through the first radio frequency module, where the network residing request is used to instruct the network access device to complete network residing on the user identification card.

10. The wearable device according to claim 9, wherein the first processor is configured to receive an authentication request generated by the network access device according to the network presence request after the first processor sends the network presence request to the network access device through the first radio frequency module;

the first processor sends the authentication request to the second processor, and sends the authentication request to the communication card assembly through the second processor;

the first processor receives an authentication result sent by the second processor, wherein the authentication result is received by the second processor from the communication card assembly, and the authentication result is obtained by the communication card assembly performing authentication on a user identity identification card according to the authentication request;

the first processor sends the authentication result to the network access equipment through the first radio frequency module, and the authentication result is used for indicating the network access equipment to complete network residence on the user identity identification card.

11. The wearable device of claim 9, wherein the first processor is further configured to, before receiving the user identification card information sent by the second processor, turn off a first system corresponding to the first processor when detecting that the wearable device is in a power saving mode; the second processor is connected with the communication card assembly; when the wearable device is switched to a normal use mode from the power saving mode, the first system is started, and the first processor receives the user identification card information sent by the second processor.

12. A communication card assembly is characterized by comprising a card reading module, a user identity identification card and a communication module, wherein the card reading module is respectively connected with the user identity identification card and the communication module;

the card reading module is used for reading a user identification card to obtain user identification card information and sending the user identification card information to the communication module;

the communication module is used for sending the user identity identification card information to the wearable device, the user identity identification card information is used for indicating the wearable device to receive the user identity identification card information through a second processor, the user identity identification card information is sent to the first processor, and a network residence request corresponding to the user identity identification card information is generated through the first processor; and sending the network residing request to network access equipment through the first processor, wherein the network residing request is used for indicating the network access equipment to complete the network residing of the user identity identification card.

13. The communication card assembly of claim 12, further comprising a second radio frequency module;

the communication card assembly is used for closing the second radio frequency module and establishing communication connection with the wearable device through the communication module when the communication card assembly detects that the distance between the communication card assembly and the wearable device is within a preset distance range; and

and when the distance between the wearable device and the mobile terminal is detected to exceed the preset distance range, the second radio frequency module is opened, and the mobile terminal is subjected to network residence through the second radio frequency module.

14. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the method according to any one of claims 1 to 8.

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