CN117119512A - Icon display control method and device - Google Patents

Abstract

The application provides an icon display control method and device, wherein the method comprises the following steps: under the scene that the terminal currently works in a DSDA mode, the first SIM card resides in a cell of a first network system supported by the DSDA mode and the first SIM card is in a round of call: if the second SIM card is currently in a preset first scene, displaying a signal icon of the second SIM card as a first signal icon, wherein the first signal icon is used for indicating that both the data service and the voice service of the second SIM card are in an available state; if the second SIM card is currently in a preset second scene, the signal icon of the second SIM card is displayed as a second signal icon, the second signal icon is used for indicating that both the data service and the voice service of the second SIM card are in an unavailable state, and the preset second scene indicates that the second SIM card is in a network-free state but the second signal icon is different from the corresponding signal icon when the SIM card is in the network-free state.

Description

Icon display control method and device

Technical Field

The present application relates to the field of communications, and in particular, to a method and apparatus for controlling icon display.

Background

The terminal with two subscriber identity modules (Subscriber Identity Module, SIM) inserted may be in a dual-card dual-pass (Dual SIM dual active, DSDA) mode, where the terminal is able to sense the network signal status of one SIM card when the terminal is talking over the other SIM card in the DSDA mode. And when the network signal state of the other SIM card is perceived to be no network signal, the signal icon of the other SIM card is displayed as a network-off icon, and the network-off icon is used for indicating that the other SIM card is in the network-free state.

Disclosure of Invention

The application provides an icon display control method and device, which are used for optimizing the signal icon display of a double card of a terminal in a DSDA mode and improving user experience. Some embodiments of the present application provide the following technical solutions:

in a first aspect, the present application provides an icon display control method, applied to a terminal, where the terminal has two SIM card slots, and in a case where the two SIM card slots are respectively inserted into a first SIM card and a second SIM card, the method includes: under the scene that the terminal currently works in a DSDA mode, the first SIM card resides in a cell of a first network system supported by the DSDA mode and the first SIM card is in a round of call: if the second SIM card is currently in a preset first scene, displaying a signal icon of the second SIM card as a first signal icon, wherein the first signal icon is used for indicating that both the data service and the voice service of the second SIM card are in an available state; if the second SIM card is currently in a preset second scene, the signal icon of the second SIM card is displayed as a second signal icon, where the second signal icon is used to indicate that both the data service and the voice service of the second SIM card are in an unavailable state, and the preset second scene indicates that the second SIM card is in a network-free state, but the second signal icon is different from the corresponding signal icon when the SIM card is in the network-free state, so that in a scene that the terminal is currently working in the DSDA mode and the first SIM card performs a round of call, the signal icon of the second SIM card can display different signal icons according to different scenes (such as the first scene and the second scene) where the second SIM card is located, so that the signal icon of the second SIM card is personalized to be displayed according to the scene where the second SIM card is located, the display of the signal icon of the double card where the terminal is in the DSDA mode is optimized, and the user experience is improved. And in a preset second scenario where the signal icon of the second SIM card is different from the corresponding signal icon when the SIM card is in the no-network state, whereby even if the preset second scenario where the second SIM card is in the no-network state, the signal icon of the second SIM card displays a signal icon that is different from a signal icon conventionally displayed when one SIM card is in the no-network state, such that by operating the terminal in the DSDA mode currently, performing a first round of call with the first SIM card, and the second SIM card being in the no-network state, the signal icon of the second SIM card does not show that the second SIM card is in the no-network state, so that the user does not perceive that the second SIM card is in the no-network state in the specific scenario (in the specific scenario, although the second SIM card is actually in the no-network state, if the signal icon of the second SIM card is displayed as a signal icon conventionally displayed when the terminal is in the no-network state, the second SIM card is actually considered as being in the no-network state), the user can not feel that the second SIM card is in the no-network state in the specific scenario, and the user can feel that the second SIM card is in the no-network state in the specific scenario, and the user is really thinkable that the terminal is in the current state when the second SIM card is actually in the network state, and the second SIM card is actually in the network state, DSDA capability may be the ability of a terminal in DSDA mode to access the internet with one SIM card during the session with another SIM card. The signal icon corresponding to the SIM card in the network-free state can be understood as a signal icon conventionally displayed when the SIM card is in the network-free state.

In one possible implementation manner, further, in a scenario where the terminal is currently operating in DSDA or DSDS mode and the first SIM card is not communicating, if the second SIM card is currently in the preset second scenario, the signal icon of the second SIM card is displayed to be the same as the signal icon corresponding to when the SIM card is in the network-free state. It can be understood that in this case, since the first SIM card is not currently talking, if the signal icon of the second SIM card is displayed to be the same as the signal icon corresponding to the SIM card in the no-network state, the signal icon of the second SIM card may be displayed in a conventional manner to be the same as the signal icon corresponding to the SIM card in the no-network state, so as to prompt the user of the actual network signal condition corresponding to the current second SIM card to the terminal.

In one possible implementation manner, further, in a scenario where the terminal is currently operating in the DSDS mode and the first SIM card is performing a round of call, the signal icon of the second SIM card is displayed to be the same as the second signal icon. The second signal icon is used for indicating that both the data service and the voice service of the second SIM card are in an unavailable state. It can be appreciated that in this case, the user knows that the terminal is currently operating in DSDS mode, and that neither icon displayed as a signal icon of the second SIM card causes a misunderstanding to the user of the terminal as to whether the terminal actually supports DSDA mode; in addition, because the terminal is currently working in DSDS mode and the first SIM card is making a round of call, the second SIM card is not capable of being made for data service and voice service, so that the signal icon of the second SIM card can be displayed as the same as the second signal icon to prompt the user of the capability that the terminal can actually be provided to the user.

In some examples, the voice service includes an emergency call voice service, and the emergency call voice service of the second SIM card is in an unavailable state when the signal icon of the second SIM card is displayed as the second signal icon; when the signal icon of the second SIM card is displayed as the signal icon corresponding to the second SIM card in the no-network state, the emergency call voice service of the second SIM card is in an available state, and when the second SIM card is in the no-network state, the signal icon of the second SIM card is generally displayed as a network-disconnection icon (the network-disconnection icon can be understood as the signal icon corresponding to the SIM card in the no-network state, i.e. a band x icon), such as the signal icon labeled 14 in fig. 3. In the first preset scene, the signal icon of the second SIM card displays the signal intensity of the second SIM card, such as the signal icon labeled 12 in fig. 1, so as to display the real network signal state of the second SIM card in real time through the signal icon of the second SIM card, thereby improving the user experience.

In a possible implementation manner, the preset first scenario includes that the second SIM card resides in any one of a first cell and a second cell, where the first cell is a cell supporting a second network system of a DSDA mode, the first network system and the second network system are one combination of system combinations of the DSDA mode supported by the terminal, the second cell is a cell corresponding to a first frequency band supporting the DSDA mode in the second network system, the first SIM card resides in a cell corresponding to a second frequency band of the first network system, and the first frequency band and the second frequency band are one combination of frequency bands supporting the DSDA mode corresponding to the system combination of the DSDA mode supported by the terminal; and/or the preset second scene comprises any one of a non-service area where the terminal is currently located in the second SIM card, a cell coverage where the terminal is currently located in a system combination which does not support the DSDA mode, and a cell coverage where the terminal is currently located in a system combination which supports the DSDA mode but does not support the frequency band combination of the DSDA mode. When the second SIM card is in a preset second scene, the first SIM card resides in a cell corresponding to a first network system supporting the DSDA mode and one frequency band (such as a second frequency band) in the frequency band combination supporting the DSDA mode, wherein the second frequency band belongs to one frequency band of the first network system.

If a system combination supporting a DSDA mode is preset by the terminal, for example, the system combination supporting the DSDA mode comprises a first network system and a second network system, and when the first SIM card resides in a cell of the first network system and the second SIM card resides in a cell of the second network system, the terminal is determined to be in a preset first scene in the process of carrying out one round of call through the first SIM card; if the first SIM card resides in the cell of the first network system and the second SIM card does not reside in the cell of the second network system, determining that the second SIM card is in a preset second scene in the process of carrying out one round of call through the first SIM card by the terminal. If a frequency band combination supporting the system combination of the DSDA mode is preset by the terminal, for example, the frequency band combination supporting the system combination of the DSDA mode comprises a second frequency band of a first network system and a first frequency band of the second network system, when a first SIM card resides in a cell of the second frequency band of the first network system and a second SIM card resides in a cell of the first frequency band of the second network system, determining that the second SIM card is in a preset first scene in the process of carrying out one round of call through the first SIM card by the terminal; if the first SIM card resides in a cell of a second frequency band of the first network system, the second SIM card does not reside in the cell of the second network system or in a cell of a third frequency band of the second network system, and the second SIM card is determined to be in a preset second scene in the process of carrying out one round of call through the first SIM card, and the third frequency band is not in a frequency band combination supporting the DSDA mode.

In a preset first scene, the second SIM card resides in a cell of a second network system supporting a DSDA mode, so that the second SIM card is available in a state of having network signals, and therefore, in a scene that the terminal works in the DSDA mode and the first SIM is in a round of call, a user can be prompted that the second SIM card is in an available state through a first signal icon of the second SIM card, and the user can perform data services through the second SIM card. In a preset second scene, the second SIM card is located in a non-service area of the second SIM card or in a cell coverage area which does not support a DSDA mode, so that the second SIM card is in a state without network signals, but at the moment, a second signal icon displayed by the second SIM card is different from a signal icon corresponding to the state without network of the second SIM card, therefore, the second SIM card is not displayed in the state without network through the second signal icon, a user cannot perceive that the second SIM card is in the state without network, the probability that the user mistakenly uses the terminal without DSDA capability is reduced, and user experience is improved.

In a possible implementation manner, the second signal icon is a funnel icon, where the funnel icon is a signal icon labeled 13 in fig. 1, and indicates that the data service and the voice service of the second SIM card are in an unavailable state through the funnel icon, and the signal icon corresponding to the SIM card in the network-free state is a band x icon.

In one possible implementation, the method further includes: and when the second SIM card is in the network-free state but the second SIM card is in the preset second scene, the signal icon of the second SIM card is continuously displayed as a second signal icon, so that the signal icon of the second SIM card can be continuously different from the signal icon of the first SIM card in the network-free state in the process of carrying out one round of call, and the user experience is improved if the second SIM card is in the network-free state but the signal icon of the second SIM card is in the preset second scene, the second SIM card is not displayed to the user in the network-free state, and the user cannot mistakenly have DSDA capability for the terminal. If the second SIM card is switched from being in a preset second scene to being in a preset first scene, the signal icon of the second SIM card is switched from displaying the second signal icon to be the first signal icon, and similarly, if the second SIM card is switched from being in the preset first scene to being in the preset second scene, the signal icon of the second SIM card is switched from displaying the first signal icon to be the second signal icon, so that the signal icon of the second SIM card accords with the scene in which the second SIM card is positioned, the display of the signal icon of the second SIM card is optimized, and the user experience is improved.

In the scenario that the signal icon of the second SIM card is continuously displayed as the second signal icon, the terminal may prohibit refreshing of the network signal information of the second SIM card, for example, the systemUI of the terminal prohibits refreshing of the network signal information of the second SIM card, so that the signal icon of the second SIM card may be continuously displayed as the second signal icon. In some examples, the inhibiting of refreshing the network signal information of the second SIM card may be that the Modem of the terminal no longer reports the network signal information of the second SIM card to the systemUI; in other examples, the network signal information of the second SIM card is prohibited from being refreshed, and the terminal Modem reports the network signal information of the second SIM card to the systemUI, but the systemUI ignores the network signal information of the second SIM card. The systemUI may prohibit refreshing of the signal icon of the second SIM card with the network signal information of the second SIM card so that the signal icon of the second SIM card is continuously displayed as the second signal icon in a preset second scene where the second SIM card is continuously located.

In one possible implementation, the method further includes: after the first SIM card is finished, the signal icon of the second SIM card is switched from displaying the second signal icon to displaying a third signal icon, wherein the third signal icon is used for indicating that the data service and the voice service of the second SIM card are in available states. The third signal icon is the same as the first signal icon in type, for example, the third signal icon may be the signal icon labeled 12 in fig. 1, and both the third signal icon and the first signal icon are used for displaying the signal strength of the second SIM card, but the signal strength of the third signal icon and the signal strength of the first signal icon may be the same or different.

In some examples, after the first SIM card session ends, the second SIM card may select one history signal icon from the set of history signal icons, where each history signal icon in the set of history signal icons is used to indicate that both data services and voice services of the second SIM card are available. The selected historical signal icon may be a historical first signal icon used when the second SIM card is switched from a preset first scene to a preset second scene, the use time of the historical first signal icon is closest to the time when the first SIM card is terminated, so as to provide a historical signal icon with higher reference, and after the first SIM card is terminated, the terminal is located in a cell coverage area corresponding to the historical first signal icon with higher probability, so that network signal information displayed by the signal icon of the second SIM card may be closer to network reality of the second SIM card. If each historical signal intensity is recorded in the historical signal icon set, after the first SIM card is finished, selecting one of the historical signal intensities recently displayed by the signal icons of the second SIM card, wherein the historical signal intensity recently displayed can be the historical signal intensity of the second SIM card which is used in a preset first scene for the last time before the first SIM card is finished, and after the first SIM card is finished, the possibility that the terminal is positioned in the cell coverage area of the historical signal intensity is higher, so that the signal intensity displayed by the signal icons of the second SIM card can be more similar to the network reality of the second SIM card. In this way, after the first SIM card session is completed, the signal icon of the second SIM card may smoothly transition from displaying the second signal icon to a historical first signal icon.

In some examples, after the first SIM card session ends, the signal icon of the second SIM card may display a designated third signal icon, so that the signal icon of the second SIM card may be quickly switched to the designated third signal icon, thereby accelerating the switching efficiency.

In one possible implementation, the method further includes: after the signal icon of the second SIM card is switched from displaying the second signal icon to displaying the third signal icon, acquiring network signal information searched by the second SIM card after the first SIM call is ended; the signal icon of the second SIM card is switched from displaying the third signal icon to displaying the fourth signal icon, and the fourth signal icon corresponds to the acquired network signal information searched by the second SIM card, so that the signal icon of the second SIM card is matched with the network signal information searched by the second SIM card, the network signal information searched by the second SIM card is displayed in real time by utilizing the fourth signal icon of the second SIM card, and a user can conveniently know the network signal state of the second SIM card. If the network signal information includes a service status, a signal strength and an operator name, the fourth signal icon of the second SIM card may display the signal strength of the second SIM card. The fourth signal icon may be the signal icon labeled 12 in fig. 1.

In one possible implementation manner, after the signal icon of the second SIM card is switched from displaying the second signal icon to displaying the third signal icon, obtaining the network signal information searched by the second SIM card after the first SIM call is ended includes: if the system UI in the terminal receives the first network signal information of the second SIM card reported by the modem processor in the terminal before the timer in the terminal is overtime, the first network signal information of the second SIM card is used as the network signal information searched by the second SIM card; if the system UI in the terminal does not receive the network signal information of the second SIM card reported by the modem processor in the terminal before the timer in the terminal is overtime, the system UI sends a second SIM card network information inquiry request to the modem processor, and the modem processor sends the second network signal information of the second SIM card to the system UI, wherein the second network signal information of the second SIM card is the network signal information searched by the second SIM card, so that the system UI can acquire the latest network signal information of the second SIM card in time, and the possibility of missing the network signal information of the second SIM card is reduced.

In one possible implementation manner, if the second SIM card is currently in the preset second scenario, displaying the signal icon of the second SIM card as the second signal icon includes: if the second SIM card is currently in a preset second scene, the terminal is switched from working in a DSDA mode to working in a DSDS mode; and controlling the signal icon of the second SIM card to be displayed as a second signal icon according to the operation of the terminal in the DSDS mode.

In one possible implementation, the switching from operating in DSDA mode to operating in DSDS mode includes: the system UI in the terminal is switched from the DSDA mode to the DSDS mode, the system UI is used for controlling the display of the signal icons of the second SIM card, so that the control of the display of the signal icons of the second SIM card is realized through the control of the working mode of the system UI in the terminal, the working modes of other modules in the terminal can be maintained in the DSDA mode, and therefore, the adjustment of the working mode of the terminal is reduced in the control of the display of the signal icons of the second SIM card.

In one possible implementation, the method further includes: presetting network configuration information supporting a DSDA mode, wherein the network configuration information comprises a system combination supporting the DSDA mode and/or a frequency band combination under a system supporting the DSDA mode; selecting target network configuration information from preset network configuration information supporting a DSDA mode according to a first network system, wherein the target network configuration information is the network configuration information supporting the DSDA mode, which is selected according to the first network system and related to a first SIM card; receiving measurement configuration information sent by network equipment, wherein the measurement configuration information comprises a first frequency point and a second frequency point; if the first frequency point in the measurement configuration information belongs to the frequency point of the second network system in the target network configuration information, preferentially measuring the first frequency point; when the signal intensity of the first frequency point meets the cell switching condition, the second SIM card resides in a cell corresponding to the first frequency point under the second network mode, so that the Modem can search the cell supporting the DSDA mode as soon as possible, the second SIM card can reside in the cell, the possibility that the second SIM card is in a network-free state is reduced, and the network can be restored as soon as possible after the second SIM card is in the network-free state.

In one possible implementation, the method further comprises at least one of: the second SIM card resides in a cell of a second network system supported by the DSDA mode; the first network system is a 4G system, and the frequency band corresponding to the cell of the first network system is at least one frequency band specified by a 4G protocol; or the first network system is a 5G system, and the frequency band corresponding to the cell of the first network system is at least one frequency band specified by a 5G protocol; or the second network system is a 4G system, and the frequency band corresponding to the cell of the second network system is at least one frequency band specified by the 4G protocol; or the second network system is a 5G system, and the frequency band corresponding to the cell of the second network system is at least one frequency band specified by the 5G protocol.

In a second aspect, the present application provides a terminal comprising: one or more processors and memory; the memory is used for storing computer program codes, the computer program codes comprise computer instructions, and when one or more processors execute the computer instructions, the terminal executes the icon display control method.

In a third aspect, the present application provides a readable computer storage medium comprising computer instructions which, when run on a terminal, cause a processor in the terminal to perform the above-described icon display control method.

In a fourth aspect, the present application provides a chip system, applied to a terminal, the chip system including at least one processor and an interface, the interface being configured to receive instructions and transmit the instructions to the at least one processor; the at least one processor executes instructions to cause the terminal to perform the icon display control method described above. At least one processor includes a Modem processor (i.e., modem) and/or an application processor (i.e., AP, application Processor).

Drawings

FIG. 1 is a schematic diagram of a signal icon display provided by the present application;

FIG. 2 is a timing diagram of an icon display control method according to the present application;

FIG. 3 is another schematic diagram of a signal icon display provided by the present application;

FIG. 4 is a schematic diagram of an interface for displaying signal icons according to the present application;

FIG. 5 is a schematic diagram of another interface for displaying signal icons according to the present application;

FIG. 6 is a schematic diagram of another interface for displaying signal icons according to the present application;

FIG. 7 is a timing diagram of another method for controlling icon display according to the present application;

FIG. 8 is a timing diagram of an icon display control method according to the present application;

FIG. 9 is a timing diagram of an icon display control method according to the present application;

FIG. 10 is a timing diagram of an icon display control method according to the present application;

FIG. 11 is a timing diagram of an icon display control method according to the present application;

fig. 12 is a timing chart of a second SIM card network searching provided by the present application;

fig. 13 is a hardware configuration diagram of a terminal provided by the present application;

fig. 14 is a software architecture diagram of a terminal provided by the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present application. The terminology used in the following examples is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used in the specification of the application and the appended claims, the singular forms "a," "an," "the," and "the" are intended to include, for example, "one or more" such forms of expression, unless the context clearly indicates to the contrary. It should also be understood that in embodiments of the present application, "one or more" means one, two, or more than two; "and/or", describes an association relationship of the association object, indicating that three relationships may exist; for example, a and/or B may represent: a alone, a and B together, and B alone, wherein A, B may be singular or plural. The character "/" generally indicates that the context-dependent object is an "or" relationship.

Reference in the specification to "one embodiment" or "some embodiments" or the like means that a particular feature, structure, or characteristic described in connection with the embodiment is included in one or more embodiments of the application. Thus, appearances of the phrases "in one embodiment," "in some embodiments," "in other embodiments," and the like in the specification are not necessarily all referring to the same embodiment, but mean "one or more but not all embodiments" unless expressly specified otherwise. The terms "comprising," "including," "having," and variations thereof mean "including but not limited to," unless expressly specified otherwise.

The plurality of the embodiments of the present application is greater than or equal to two. It should be noted that, in the description of the embodiments of the present application, the terms "first," "second," and the like are used for distinguishing between the descriptions and not necessarily for indicating or implying a relative importance, or alternatively, for indicating or implying a sequential order.

For convenience of explanation, technical terms related to the embodiments of the present application will be explained first:

A wireless communication system may be understood to include terminals and network devices. A terminal may also be referred to as a terminal device (Terminal Equipment), user Equipment (UE), mobile station, mobile terminal, etc. The terminal may be a cell phone, tablet computer, computer with wireless transceiver function, virtual reality terminal, augmented reality terminal, wireless terminal in industrial control, wireless terminal in unmanned, wireless terminal in teleoperation, wireless terminal in smart grid, wireless terminal in transportation security, wireless terminal in smart city, wireless terminal in smart home, etc. The application does not limit the specific technology and the specific equipment form adopted by the terminal.

The network device is an access device that a terminal accesses to the mobile communication system in a wireless manner, and may be a base station (base station), an evolved NodeB (eNodeB), a transmitting and receiving point (transmissionreception point, TRP), a next generation NodeB (gNB) in a 5G mobile communication system, a base station in a future mobile communication system, or an access node in a WiFi system; the present application may also be a module or unit that performs a function of a base station part, for example, a Central Unit (CU) or a Distributed Unit (DU). The application is not limited to the specific technology and the specific equipment form adopted by the network equipment.

No service area: areas without network signal coverage.

Service area: there is an area covered by the network signal.

Signal icon of SIM card: the signal icons of the SIM card comprise a signal icon, a funnel icon and a network-off icon for displaying signal intensity. The signal icon displaying the signal intensity is used for displaying the signal intensity of the SIM card so as to indicate that the SIM card is in an available state, wherein the available state of the SIM card means that both the data service and the voice service of the SIM card are in an available state; the signal icon for displaying the signal intensity may be shown with reference to fig. 1, in which the signal icon denoted by 11 in fig. 1 is the signal icon of the first SIM card, the signal icon denoted by 12 is the signal icon of the second SIM card, the signal intensity of the first SIM card is displayed by using the signal icon 11 of the first SIM card, and the signal intensity of the second SIM card is displayed by using the signal icon 12 of the second SIM card; the network dropping icon may be a signal icon denoted by 14 in fig. 3, where the network dropping icon is used to prompt that the SIM card is in a network-free state, that is, the SIM card has no network signal, and the SIM card has no network signal caused by a problem of the network signal of the SIM card, and in the network-free state of the SIM card, the emergency call voice service is in an available state, but the voice service other than the emergency call voice service in the data service and the voice service is in an unavailable state, and the emergency call voice service is one of the voice services; the funnel icon may be a signal icon, which is labeled 13 in fig. 1, and is used to indicate that the SIM card is in an unavailable state, where the SIM card is in an unavailable state, that is, both the data service and the voice service of the SIM card are in an unavailable state.

The network dropping icon and the funnel icon are two different concepts, and when the signal icon is the network dropping icon, the service is in an unavailable state because the SIM card has no network signal; when the signal icon is a funnel icon, the service is in an unavailable state because the terminal prohibits the use of the SIM card, such as the terminal freezes (disables) the data service of the SIM card and the voice service of the SIM card, so that the user cannot operate the SIM card, and the user cannot access the data service of the SIM card and the voice service of the SIM card. The network condition of the SIM card when the signal icon is a funnel icon is: if the terminal works in the DSDS mode, the SIM card may be in a state with network signals or in a state without network signals; if the terminal works in the DSDA mode, the SIM card is in a state without network signals.

Standard combination: the system combination is a combination of Radio access technologies (Radio Access Technology, RAT) supported by the terminal, the RAT including but not limited to 2G, 3G, 4G, 5G, etc., e.g., the RAT may include global mobile communications (Global System of Mobile Communication, GSM), code division multiple access (Code Division Multiple Access, CDMA), wideband code division multiple access (Wideband Code Division Multiple Access, WCDMA), universal mobile telecommunications system (Universal Mobile Telecommunication System, UMTS), long term evolution (Long Term Evolution, LTE), and New Radio (NR), etc. The metric combination may be a combination of at least two RATs in GSM, CDMA, WCDMA, UMTS, LTE and NR.

Frequency band combination: the frequency band combination is a frequency band combination adopted by the RAT supported by the terminal, and frequency bands adopted by different RATs can be designated in the frequency band combination.

Dual card dual standby (Dual SIM Dual Standby, DSDS): the double-card double-standby can also be called double-card double-standby single-pass, two subscriber identity modules (Subscriber Identification Module, SIM) cards inserted in a terminal supporting a DSDS mode can be in a standby state at the same time, but when the terminal performs one round of call through one SIM card, the other SIM card is in an unavailable state, and if the terminal is a calling party, one round of call comprises calling, call establishment and call in-process; if the terminal is the called party, a round of call includes receiving a call, establishing a call, and calling.

Fig. 1 shows two examples of the display of the signal icons of the first SIM card and the second SIM card in the case where the terminal is in the DSDS mode and the terminal is a calling party, wherein 11 in (1) in fig. 1 is the signal icon of the first SIM card, 12 is the signal icon of the second SIM card, and before the terminal does not make a call, the signal icon of the first SIM card 11 and the signal icon of the second SIM card 12 are respectively displayed with network signals, such as the signal icon of the first SIM card 11 displays the signal intensity of the first SIM card, and the signal icon of the second SIM card 12 displays the signal intensity of the second SIM card. And starting a round of call with the contact person 1 through the first SIM card at the terminal, and displaying an interface shown in (2) in fig. 1 by the terminal. In fig. 1 (2), 11 is a signal icon of a first SIM card, 13 is a signal icon of a second SIM card, and when the first SIM card starts a call of a round of call, the signal icon 11 of the first SIM card continues to display that the first SIM card has a network signal, and the signal icon 13 of the second SIM card is displayed as a funnel icon, where the funnel icon is used to prompt a user that the second SIM card corresponding to the signal icon is in an unavailable state. In the case that the terminal performs a round of call through the first SIM card in the DSDS mode, the terminal may freeze the second SIM card, so that the SIM card is in an unavailable state, and thus the user cannot use the second SIM card. Because the terminal freezes the second SIM card, the communication link between the second SIM card and the network device is broken, and the terminal cannot perceive the change of the network signal of the second SIM card, the signal icon of the second SIM card still displays as a funnel icon no matter the terminal moves to the no-service area or the service area of the second SIM card during the current communication process through the first SIM card, and particularly, when the terminal moves to the no-service area of the second SIM card, the signal icon of the second SIM card does not display no network signal (may also be called as a network-off state, and the network-off state may also be called as a no-network state).

Fig. 2 shows a flow of an icon display control method of a terminal in a DSDS mode, which may include the steps of:

s10, the terminal is inserted into the first SIM card and the second SIM card, and the power-on is completed through systemUI, telephony, RIL (systemUI, telephony, RIL can be included in an AP of the terminal) and the Modem. The first SIM card and the second SIM card may share one Modem, and monitor the network signal states of the first SIM card and the second SIM card by using the Modem to obtain network signal information of each SIM card, where if there is a network signal, the network signal may be any one of a cell in which the terminal resides in a system combination supporting the DSDS mode and a cell in which the terminal resides in a frequency band corresponding to a frequency band combination supporting the system combination of the DSDS mode, where the service state, the signal strength, the operator name, and the like are reported by using the Modem under the condition that the network signal is a network signal.

And S11, after the Modem determines that the double cards are registered, the Modem reports the service state, the signal strength and the name of an operator to the system UI through RIL and telephenyl. The dual card includes a first SIM card and a second SIM card, and the Modem may report the service status, signal strength, and carrier name of the first SIM card to the systemUI, and report the service status, signal strength, and carrier name of the second SIM card to the systemUI. The double-card registration is that the first SIM card and the second SIM card complete registration at the network side, so that the signal icon of the first SIM card displays the signal intensity of the first SIM card and the signal icon of the second SIM card displays the signal intensity of the second SIM card, and the user can use the first SIM card and the second SIM card.

S12, the systemUI controls the signal icon of the first SIM card to display the signal intensity and the operator name of the first SIM card, and the signal icon of the second SIM card to display the signal intensity and the operator name of the second SIM card, so that the signal icons of the double cards respectively display the corresponding signal intensity and the operator name.

S13, the Modem reports that the terminal is in a DSDS mode to the system UI through RIL and telephone. The DSDS mode reporting may be performed before step S11 or in synchronization with step S11.

And S14, when the system UI determines that the first SIM card initiates the call, sending information for indicating the first SIM card to initiate the call to the Modem through the telephone and the RIL.

And S15, after the first SIM card is determined to initiate the call, the systemUI controls the signal icon of the second SIM card to be displayed as a funnel icon, as shown in the figure 1.

S16, after receiving the information for indicating the first SIM card to initiate the call, the Modem state corresponding to the second SIM card is frozen so as not to report the service state, the signal strength and the operator name of the second SIM card. Those skilled in the art will appreciate that: in the DSDS mode, the first SIM card and the second SIM card share one Modem, and the fact that the Modem state corresponding to the second SIM card is frozen can be understood that the Modem freezes the second SIM card, the communication link between the second SIM card and the network device is disconnected, and the Modem cannot sense the network signal state of the second SIM, so that the Modem does not report the service state, the signal strength and the operator name of the second SIM card to the systemUI.

It should be noted that, the Modem may report network signal information related to the SIM card to the systemUI, where the network signal information may include service states, where the service states include a service state and a no-service state, where the service states (may also be referred to as a network signal state) are used to indicate that there is a network signal, and where the service states are service states, the network signal information may also include signal strength and an operator name; the out-of-service state (also referred to as a dropped state) is used to indicate that there is no network signal. When the Modem state corresponding to the second SIM card is frozen, if the service state is the service state, the Modem does not report the service state, the signal strength and the operator name of the second SIM card; if the service state is the no-service state, the Modem does not report the no-service state of the second SIM card.

And S17, after determining that the call of the first SIM card is hung up, the system UI sends information for indicating the call is ended to the Modem through the telephone and the RIL.

And S18, after receiving the information for indicating the call completion, the Modem removes the freezing of the Modem state corresponding to the second SIM card, and reports the service state, the signal strength and the operator name of the second SIM card. Those skilled in the art will appreciate that: in the DSDS mode, the removal of the freezing of the Modem state corresponding to the second SIM card may be understood as that the Modem removes the freezing of the second SIM card, and the Modem may sense the network signal state of the second SIM on the communication link connection between the second SIM card and the network device, so that the Modem may report the service state, the signal strength, and the operator name of the second SIM card to the systemUI.

When the service state is the service state, the Modem can report the service state, the signal strength and the name of an operator of the SIM card to the systemUI; when the service state is the no-service state, the Modem can report the no-service state of the SIM card to the systemUI.

And S19, the systemUI controls the signal icon of the second SIM card to be switched from being displayed as a funnel icon to displaying the reported signal intensity and the name of the operator.

When the terminal is in a DSDS mode and the terminal performs one round of call through one of the first SIM card and the second SIM card, the non-call SIM card is frozen, and the non-call SIM card is unfrozen after the call is ended, so that the terminal cannot sense the network signal state of the non-call SIM card in the process of performing one round of call through the one SIM card, the signal icon of the non-call SIM card can be displayed as a funnel icon, and thus, a user cannot sense when the non-call SIM card falls off the network, and the user experience is good.

Double-card double pass (Dual SIM dual active, DSDA): the dual-card dual-pass can also be called as dual-card dual-standby dual-pass, and the terminal supporting the DSDA mode has the capability of surfing the internet by using one SIM card in the process of calling the other SIM card (DSDA capability for short) because the two SIM cards have concurrent capability, so that the other SIM card is in an available state when the terminal performs one-round call through the one SIM card. In the DSDA mode of the terminal, the signal icon of one SIM card is not displayed as a funnel icon when the other SIM card makes a round of call, but the SIM card has a network signal (for example, the signal strength of the SIM card is displayed). For example, the terminal is located in a service area of a non-talking SIM card, and a signal icon of the non-talking SIM card can display signal strength; optionally, the signal icon of the non-talking SIM card may also display an operator name, which can be applied to the embodiments of the present application; the terminal moves to the non-service area of the non-talking SIM card, and the signal icon of the non-talking SIM card can display the network-dropping icon.

For example, a terminal supporting DSDA mode (hereinafter abbreviated as DSDA supporting) inserts a first SIM card and a second SIM card, a user makes a call using the first SIM card, and the terminal processes in this environment as follows:

1. the terminal is in a DSDA mode, and the display of the signal icon of the second SIM card is controlled according to the DSDA mode, wherein the display of the signal icon of the second SIM card can be: the signal icon of the second SIM card may display the signal strength and the name of the operator under the condition that the second SIM card has a network signal (i.e., in a state of having a network signal), or the signal icon of the second SIM card may display the signal strength and the RAT supported by the second SIM card; the signal icon of the second SIM card may display the network-drop icon under the condition that the second SIM card has no network signal (i.e., is in a state of no network signal). As shown in fig. 3, the terminal is in DSDA mode, and before the terminal does not talk, the signal icons of the first SIM card and the second SIM card show that each card has a network signal, e.g. in fig. 3, the signal icon 11 of the first SIM card shows the signal strength of the first SIM card, and the signal icon 12 of the second SIM card shows the signal strength of the second SIM card; when the first SIM card starts a call of a round of call, because the terminal is currently in the service area of the second SIM card, the signal icon 12 of the second SIM card still displays the signal strength of the second SIM card, as shown in (2) of fig. 3, and (2) of fig. 3 is exemplified by displaying the signal strength and the supported RAT; in the call process of the first SIM card, as the terminal moves to the no-service area of the second SIM card, the display icon of the second SIM card becomes the signal icon 14, and the signal icon 14 is the network-down icon, so as to indicate that the second SIM card has no network signal through the network-down icon, as shown in (3) in fig. 3.

The point to be described here is that the display change of the signal icon when the terminal is the calling party may be the starting time point when the call is started, and the display change of the signal icon when the terminal is the called party may be the starting time point when the call is received. As shown in fig. 1, when the terminal is in DSDS mode and the terminal is a calling party, the signal icon of the second SIM card is displayed as a funnel icon when the first SIM card starts to call; if the terminal is in DSDS mode but the terminal is the called party, the signal icon of the second SIM card is displayed as a funnel icon when the first SIM card receives the call. And under the condition that the second SIM card has no network signal, the signal icon of the second SIM card is displayed as a network-dropping icon no matter whether the terminal is a calling party or a called party in the DSDA mode.

2. The terminal moves to a non-service area of a second SIM card, and a signal icon of the second SIM card is displayed as a network dropping icon; or when the terminal moves to an area which does not support the frequency band combination of the DSDA or the standard combination of the DSDA, the terminal does not search the network through the second SIM card, because the terminal does not search the network through the second SIM card, the terminal cannot sense the network signal change of the second SIM card, and the signal icon of the second SIM card is displayed as a network dropping icon. The network searching is short for searching network, mainly searching network signal state. If the terminal is in the DSDA mode and the terminal performs a round of call through the first SIM card, the terminal can search the network through the second SIM card under the combination of the standard and the frequency band supporting the DSDA mode.

3. Before the user hangs up the call of the first SIM card, if the terminal is in the non-service area of the second SIM card or moves to the area of the frequency band combination which does not support DSDA or the standard combination which does not support DSDA, the signal icon of the second SIM card is continuously displayed as a network-dropping icon. After the user hangs up the call of the first SIM card, if the terminal searches the network signal of the second SIM card, the signal icon of the second SIM card is changed from displaying the network signal to displaying the network signal, such as displaying the signal intensity of the second SIM card, the name of the operator, and the like.

Therefore, when the terminal supporting the DSDA mode performs a round of call on the first SIM card, the objective reason that the signal icon of the second SIM card is displayed as the network-drop icon is as follows: and moving to a non-service area of the second SIM card, or moving to an area which does not support the combination of frequency bands of DSDA or the combination of systems of DSDA. For the user, when the signal icon of the second SIM card is displayed as the network-off icon, the terminal cannot access the network through the second SIM card currently, and the signal icon does not accord with the DSDA capability of the terminal, so that the user can misuse the terminal to have no DSDA capability, and the user experience is reduced.

Some embodiments of the present application provide an icon display control method, where the icon display control method is applied to a terminal, the terminal has two SIM card slots, the two SIM card slots are respectively inserted into a first SIM card and a second SIM card, and a scenario of the icon display control method is that the terminal currently works in a DSDA mode, the first SIM card resides in a cell of a first network system supported by the DSDA mode, and the first SIM card is in a round of call, and in the scenario, the icon display control method can control display of a signal icon of the second SIM card according to a current scenario of the second SIM card, where the signal icon of the second SIM card is different from a signal icon corresponding to when the second SIM card is in a no-network state, so that in a round of call process of the first SIM card, the signal icon of the second SIM card can not display the signal icon corresponding to when the second SIM card is in the no-network state, and in a round of call process of the first SIM card, no network state of the second SIM card is not visually displayed, so that a user does not feel that the second SIM card is dropped from a network, and experience of the user is improved.

Fig. 4 is an interface schematic diagram illustrating an icon display control method, and fig. 4 (11) illustrates that before the terminal does not make a round of call, the signal icon 11 of the first SIM card displays the signal strength of the first SIM card, and the signal icon 12 of the second SIM card displays the signal strength of the second SIM card; after a call of a round of call is started through the first SIM card, because the second SIM card is in a state of having a network signal, the signal icon 12 of the second SIM card still displays the signal strength of the second SIM card, as shown in (12) in fig. 4 and (13) in fig. 4, and in the call through the first SIM card and the call through the first SIM card, the terminal is in the state of having the network signal of the second SIM card, and the signal icon 12 of the second SIM card still displays the signal strength of the second SIM card; in the process of the first SIM card session, as the terminal moves the second SIM card to switch from the network signal state to the network disconnection state, as shown in (14) of fig. 4, the signal icon of the second SIM card is switched from the signal icon 12 to the signal icon 15, where the signal icon 15 is a funnel icon, and the funnel icon indicates that the second SIM card is in an unavailable state.

In the first SIM card session process, if the second SIM card is always in the off-network state, the terminal may display the signal icon of the first SIM card and the signal icon of the second SIM card in a manner shown in (14) in fig. 4, where the signal icon 11 of the first SIM card displays the signal strength of the first SIM card, and the signal icon 15 of the second SIM card displays the funnel icon.

Fig. 5 shows another interface diagram of the icon display control method, wherein the interface diagram shown in fig. 5 is continued to (14) in fig. 4, and shows a change of the signal icon of the second SIM card after the first SIM card session is completed. In the process of the first SIM card session, the second SIM card is continuously in a dropped network state, continuing to (14) in fig. 4, after the first SIM card session is ended, the signal icon of the second SIM card is changed, as shown in (15) in fig. 5, and the signal icon of the second SIM card is switched from the signal icon 15 to the signal icon 12, so that the signal intensity of the second SIM card is displayed through the signal icon 12. In some examples, the signal strength of the second SIM card displayed by the signal icon 12 of the second SIM card in (15) in fig. 5 may be a preset signal strength. In some examples, the signal strength of the second SIM card displayed by the signal icon 12 of the second SIM card in (15) in fig. 5 may be one of a set of historical signal strengths of the second SIM card, such as one of the historical signal strengths that is most recently displayed by the signal icon of the second SIM card in the set of historical signal strengths, thereby providing a historical signal strength with a higher reference, and the signal strength of the second SIM card before the second SIM card falls off the network is displayed by the signal icon 15 of the second SIM card in (15) in fig. 5. In a round of call of the first SIM card, the signal intensity of the second SIM card before the second SIM card is switched to the off-network state is recorded in the historical signal intensity set, and the signal intensity of the second SIM card before the second SIM card is switched to the off-network state is one historical signal intensity recently displayed by the signal icon of the second SIM card, so that after the first SIM card is finished, the signal intensity of the second SIM card before the second SIM card is switched to the off-network state is displayed by the signal icon of the second SIM card. After the first SIM card session is finished, the possibility of the coverage area of the cell of the signal intensity of the second SIM card before the terminal switches to the off-network state in the second SIM card is greater, so that the signal intensity displayed by the signal icon 12 of the second SIM card may be closer to the network reality of the second SIM card.

After the signal icon 12 of the second SIM card displays the signal strength of the second SIM card, the signal icon 12 of the second SIM card may change according to the change of the network signal information of the second SIM card, where the network signal information of the second SIM card may change by changing the signal strength of the cell in which the second SIM card resides. As shown in (16) of fig. 5, when the signal strength of the cell in which the second SIM card resides becomes weak, the signal icon 12 of the second SIM card shows the weakened signal strength.

Fig. 6 shows still another interface diagram of the icon display control method, wherein the interface diagram shown in fig. 6 is continued to (14) in fig. 4, and shows a change situation of the signal icon of the second SIM card during one round of call by the first SIM card. In the process of a round of call of the first SIM card, as the terminal moves to the service area of the second SIM card, the second SIM card is switched from the off-network state to the network signal state, which means that the second SIM card searches for network signal information, and at the moment, the second SIM card can be used, then the signal icon of the second SIM card correspondingly changes, as shown in (17) in FIG. 6, the signal icon of the second SIM card is switched from the signal icon 15 to the signal icon 12, and the signal icon 12 of the second SIM card displays the signal intensity of the second SIM card so as to indicate that the second SIM card is in a usable state through the signal icon 12 of the second SIM card. Therefore, in the first SIM card performs a round of call, if the second SIM card is switched from the off-network state to the network signal state, the signal icon 12 of the second SIM card can display the signal intensity of the second SIM card, so that the user can sense the signal intensity of the second SIM card in real time, and the user can use the second SIM card in the first SIM card performs a round of call, thereby improving the user experience.

The flow of the icon display control method according to some embodiments of the present application is described below with reference to the timing chart. Fig. 7 shows a flow of an icon display control method of a terminal in a DSDA mode, where after a corresponding terminal is called through a first SIM card, a second SIM card drops off the network, and the second SIM card drops off the network until a call ends, where the icon display control method may include the following steps:

s10 to S12: please refer to steps S10 to S12 in the icon display control method shown in fig. 2.

S20, the Modem reports to the system UI that the terminal is in a DSDA mode through RIL and telephosy. The DSDA mode reporting may be performed before step S11 or in synchronization with step S11.

S21, when the system UI determines that the first SIM card initiates the call, the system UI sends information for indicating the first SIM card to initiate the call to the Modem through the telephone and the RIL.

S22, after receiving the information for indicating the first SIM card to initiate the call, the Modem continues to search the network signal state of the second SIM card, and after searching the network signal state of the second SIM card, the Modem reports the network signal state to the systemUI through RIL and test. The network signal state of the second SIM card may be referred to as a service state of the second SIM card, and when the network signal state is the service state, the Modem reports the service state, the signal strength and the operator name to the system ui through RIL and telephone; when the network signal state is the network-off state, the Modem reports the network-off state to the system UI through RIL and telephenyl. In step S22, the Modem searches for a service status of the second SIM card, and reports the service status, the signal strength and the name of the operator.

Those skilled in the art will appreciate that: although the first SIM card and the second SIM card share one Modem, the terminal is in a DSDA mode, the first SIM card and the second SIM card have double-card concurrency capability, the second SIM card is in an available state in the process of the first SIM card, and if the terminal is positioned under the coverage area of a cell supporting the system combination and the frequency band combination of DSDA, the Modem can search the network of the second SIM card, so that when the second SIM card has network signals, the Modem can acquire the network signal information of the second SIM card and display the network signal information through the signal icons of the second SIM card.

S23, the systemUI controls the signal icon of the second SIM card to display the signal intensity and the name of the operator of the second SIM card so as to indicate that the second SIM card has a network signal after the first SIM card is in communication, and the second SIM card is still in a usable state after the first SIM card is in communication, as shown in (1) and (2) in the above-mentioned figure 3. Therefore, if the second SIM card has a network signal in the communication process of the first SIM card, the signal icon of the second SIM card can display the signal intensity of the second SIM card, so that a user can know that the second SIM card is available and has the network signal.

And S24, after determining that the second SIM card is disconnected, the Modem reports the disconnection state of the second SIM card to the system UI through RIL and telephenyl, wherein the disconnection state is used for indicating that the second SIM card has no network signal. And after the terminal moves to a non-service area of the second SIM card or moves to a standard combination and/or a frequency band combination which do not support DSDA, the second SIM card drops off the network.

S25, after the second SIM card is received to be disconnected, the systemUI performs signal freezing on the second SIM card. The signal freezing of the second SIM card comprises the display of a signal icon of the second SIM card as a funnel icon, the freezing of the service state of the second SIM card, the signal strength and the name of an operator. The Modem may continue to search for the network of the second SIM card in the event that the systemUI freezes the second SIM card.

In some examples, the service state, signal strength, and carrier name of the freeze-refreshed second SIM card may be: the Modem does not report the service state, the signal strength and the name of an operator of the second SIM card to the system UI through the RIL and the telephone; because the systemUI no longer receives the service status, signal strength, and carrier name of the second SIM card, the display of the signal icon of the second SIM card as a funnel icon may continue until the call of the first SIM card ends.

In some examples, the service state, signal strength, and carrier name of the freeze-refreshed second SIM card may be: the Modem may continue to report the service status, signal strength, and carrier name of the second SIM card to the systemUI via RIL and testophory, but the systemUI ignores the reported service status, signal strength, and carrier name of the second SIM card. The system ui may ignore the service status, the signal strength and the operator name of the second SIM card, and may mainly target the network-off status of the second SIM card, report the network-off status to the system ui through RIL and telephenyl after determining that the second SIM card is off-network, and then the system ui may continue to freeze the second SIM card. If the second SIM card is in the off-line state continuously before the call of the first SIM card hangs up, the second SIM card is frozen continuously until the call of the first SIM card is ended.

S26, after the systemUI determines that the call of the first SIM card is hung up, information for indicating the call is ended is sent to the Modem through the telephone and the RIL.

S27, the systemUI may end the freezing of the second SIM card, and the signal icon of the second SIM card displays the service status, the signal strength and the operator name before freezing. Ending the freezing of the second SIM card means that the freezing of the second SIM card is released, and the sym ui releases the restriction that the signal icon of the second SIM card is displayed as a funnel icon, and after the releasing, the signal icon of the second SIM card may display the signal strength and the operator name of the second SIM card before the freezing, as shown in (14) of fig. 5 and (15) of fig. 5.

And S28, after the latest service state of the second SIM card is acquired, the system UI displays the latest service state of the second SIM card by the signal icon of the second SIM card. In fig. 7, the latest service status of the second SIM card may be the service status, signal strength, and carrier name of the second SIM card, and the latest signal strength and carrier name of the second SIM card are displayed through the signal icon of the second SIM card.

In the process that the terminal passes through the first SIM card, if the second SIM card is in a network disconnection state continuously, the systemUI can freeze the second SIM card, and the second SIM card can be frozen continuously until the communication of the first SIM card is finished, so that in the process that the first SIM card is communicated, a signal icon of the second SIM card does not display the network disconnection of the second SIM card to a user, the probability that the user mistakenly thinks that the terminal does not have DSDA capability is reduced, and the user experience is improved.

After the second SIM card is frozen, the systemUI may display the pre-frozen service status, signal strength, and carrier name. The service state before freezing indicates that the second SIM card has network signals, so that after the second SIM card is frozen, the signal icon of the second SIM card is smoothly transited from the display funnel icon to the display signal intensity and the operator name, the signal icon of the second SIM card does not display network dropping in the call process, and the user experience is improved. After the first SIM card is terminated, the possibility of the coverage area of the cell of the signal intensity of the second SIM card before the terminal freezes is higher, so that the signal intensity displayed by the signal icon of the second SIM card may be closer to the network reality of the second SIM card. After the signal icon of the second SIM card displays the signal strength and the carrier name before freezing, the systemUI may obtain the latest service state, signal strength and carrier name of the second SIM card from the Modem. The latest service state, the signal strength and the operator name are the latest and real network signal state of the second SIM card perceived by the Modem, so that the signal icon of the second SIM card can display the latest and real network signal state of the second SIM card, the display of the signal icon of the second SIM card is the same as the network signal state of the second SIM card, and the user experience is improved.

It will be appreciated that: in the process of the first SIM card communication, the Modem can search the network of the second SIM card, and the Modem can refresh the service state of the second SIM card and report the service state to the systemUI, so that a situation exists, wherein the situation can be that the Modem reports the service state of the second SIM card before the first SIM card communication is finished; after the first SIM card session is finished, the Modem completes the network search for the second SIM card again and reports the network search, so that in this case, the signal icon of the second SIM card may miss some network signal states of the second SIM card. For this case, fig. 8 shows an example of the systemUI obtaining the latest service state of the second SIM card, where fig. 8 illustrates that the latest service state of the second SIM card includes a service state, a signal strength, and an operator name, and may include the following steps:

s281, systemUI starts a timer after the second SIM card is frozen.

S282, judging whether the service state, the signal intensity and the operator name of the second SIM card reported by the Modem are received before the timer is overtime, and executing the step S283 if the service state, the signal intensity and the operator name of the second SIM card reported by the Modem are received before the timer is overtime; if the second SIM card has not received the service status, signal strength and operator name reported by the Modem before the timer expires, step S284 is performed.

S283, the signal icon of the second SIM card displays the signal intensity of the second SIM card and the name of the operator.

S284, the systemUI actively inquires the service state, the signal strength and the name of the operator of the second SIM card from the Modem through a telephony and an RIL.

S285, the Modem reports the service state, the signal strength and the name of the operator of the second SIM card through RIL and telephonn.

S286, the signal icon of the second SIM card displays the reported signal intensity of the second SIM card and the name of the operator.

Through the steps S281 to S286, the systemUI can timely acquire the latest network signal state of the second SIM card, so as to reduce the possibility of missing the network signal state of the second SIM card. As shown in fig. 5 (14) to fig. 5 (16), after the first SIM card session is finished, the signal icon of the second SIM card may display the signal intensity of the second SIM card before freezing; and then the systemUI can obtain the latest network signal information of the second SIM card reported by the Modem, and control the display of the signal icon of the second SIM card by utilizing the latest network signal information of the second SIM card, as in (16) in fig. 5, the signal intensity in the latest network signal information of the second SIM card is weakened and changed from the original four signal intensities to three signal intensities, and then the signal icon of the second SIM card displays the three signal intensities.

In some examples, the terminal is in DSDA mode and the systemUI freezes the second SIM card after determining that the first SIM card is talking; after the systemUI determines that the call of the first SIM is hung up, the freezing of the second SIM card is ended, so that the freezing of the second SIM card is maintained in the call process of the first SIM card, the second SIM card is not displayed even if the terminal perceives that the second SIM card is off-line in the call process of the first SIM card, and the user experience is improved. However, the second SIM card is not frozen under the condition that the first SIM card does not have a call, so that the signal icon of the second SIM card can display the network signal state of the second SIM card in real time under the condition that the first SIM card does not have a call, so that a user can know the network signal state of the second SIM card at any time, and user experience is improved. Wherein freezing the second SIM card may include the signal icon of the second SIM card being displayed as a funnel icon, freezing the service status, signal strength, and carrier name of the refreshed second SIM card. After the second SIM card is frozen, the signal icon of the second SIM card can display the service state, the signal intensity and the operator name before freezing, and then the signal icon of the second SIM card displays the latest service state, the signal intensity and the operator name of the second SIM card reported by the Modem. If the Modem determines that the second SIM card is off-line, the Modem may also report the off-line status of the second SIM card to the systemUI, so that the network signal status of the second SIM card may be displayed in real time through the signal icon of the second SIM card.

Fig. 9 shows a flow of an icon display control method of a terminal in DSDA mode, where a corresponding terminal drops a network of a second SIM card after a call through a first SIM card, but in a scenario where the second SIM card searches for a network signal in the process of the call through the first SIM card, the icon display control method may include the following steps:

s10 to S12: please refer to steps S10 to S12 in the icon display control method shown in fig. 2.

S20 to S25: please refer to steps S20 to S25 in the icon display control method shown in fig. 7.

And S30, after the second SIM card is disconnected from the network, the Modem continues to search the network of the second SIM card, and after the second SIM card is searched to be in a service state, the signal strength and the operator name of the second SIM card are reported to the system UI through the RIL and the telephone.

S31, displaying the reported signal intensity and the name of the operator of the second SIM card by the signal icon of the second SIM card.

S32, after the systemUI determines that the call of the first SIM card is hung up, information for indicating the call is ended is sent to the Modem through the telephone and the RIL.

The icon display control method shown in fig. 9 is different from the icon display control method shown in fig. 7 in that: in the first SIM card session process, the second SIM card searches for a network signal after network disconnection, so that the Modem can report the searched service state, signal strength and operator name of the second SIM card to the systemUI, and the systemUI finishes freezing the second SIM card before the first SIM card session is finished. Because the systemUI has received the latest serviced state, signal strength, and carrier name of the second SIM card before the systemUI has finished freezing the second SIM card. The latest service state, the signal strength and the operator name are the latest and real network signal state of the second SIM card perceived by the Modem, so that the signal icon of the second SIM card can display the latest and real network signal state of the second SIM card, the display of the signal icon of the second SIM card is the same as the network signal state of the second SIM card, and the user experience is improved. The corresponding interface is schematically shown in fig. 6, which will not be described in detail here.

The points to be described here are: after the second SIM card is frozen and before the call of the first SIM card hangs up, if the Modem reports to the system ui that the second SIM card is in the off-network state, the system ui may freeze the signal of the second SIM card again. Namely, in the communication process of the first SIM card, if the second SIM card is in a network-off state, the system UI can freeze signals of the second SIM card; if the second SIM card has a network signal, the systemUI can finish freezing the second SIM card, so that a signal icon of the second SIM card does not display a network-off icon in the communication process of the first SIM card, a user does not perceive that the second SIM card is off-line in the communication process of the first SIM card, and user experience is improved.

Fig. 10 shows a flow of an icon display control method of a terminal in a DSDA mode, where the icon display control method controls a signal icon of a second SIM card by controlling a working mode of a systemUI in a communication process of a first SIM card, and may include the following steps:

s10 to S12: please refer to steps S10 to S12 in the icon display control method shown in fig. 2.

S20 to S23: please refer to steps S20 to S23 in the icon display control method shown in fig. 7.

S40, the Modem searches the standard combination and the frequency band combination of all the supported DSDA of the terminal after determining that the second SIM card is off-line, and the network is not restored after searching the standard combination and the frequency band combination of all the supported DSDA. In some examples, the Modem may preset the off-network protection time, and complete searching of all supported standard combinations and frequency band combinations of the DSDA within the preset off-network protection time. The value of the off-network protection time is preset, and the embodiment is not limited.

S41, the Modem switches the operation mode of the system UI from a DSDA mode to a DSDS mode, and reports the operation mode of the switched system UI to the system UI as the DSDS mode through RIL and testephenyl. The operation mode of the systemUI defines a rule for displaying signal icons of the first SIM card and the second SIM card, wherein in the communication process of the first SIM card, if the operation mode of the systemUI is a DSDS mode, the signal icon of the second SIM card may be displayed in a manner shown in fig. 1; if the operation mode of the systemUI is DSDA mode, the signal icon of the second SIM card may be displayed as shown in fig. 3.

S42, displaying the systemUI according to a display rule of a DSDS mode: the signal icon of the second SIM card is displayed as a funnel icon.

The icon display control method shown in fig. 10 is different from the icon display control methods shown in fig. 7 and 9 in that: fig. 7 and 9 are diagrams of freezing the second SIM card at the systemUI level so that the signal icon of the second SIM card does not show the network drop icon when the second SIM card drops. The icon display control method shown in fig. 10 indicates the system ui to switch the working mode at the Modem level, and realizes the control of the signal icon of the second SIM card by switching the working mode of the system ui, specifically, when the second SIM card is off the network and the system combination and the frequency band combination of all the supported DSDA are searched and still not restored to the network, the Modem switches the working mode of the system ui from the DSDA mode to the DSDS mode, and the system ui displays according to the display rule of the DSDS mode. The display rule of the DSDS mode is that the signal icon of the other SIM card is displayed as a funnel icon in the communication process of the one SIM card, and based on the display rule, the signal icon of the second SIM card is displayed as the funnel icon in the communication process of the first SIM card, so that the signal icon of the second SIM card is controlled to be displayed as the funnel icon after the DSDA mode is switched to the DSDS mode, the terminal does not display the network signal state of the second SIM card in the communication process of the first SIM card, and therefore, a user cannot know when the second SIM card falls off the network, and the user experience is improved. The interface schematic diagrams corresponding to the icon display control method shown in fig. 10 may refer to (11) in fig. 4 to (14) in fig. 4, and before the terminal does not talk, the signal icons of the first SIM card and the second SIM card display the signal intensities of the respective cards; after the communication is started through the first SIM card, the signal icon of the second SIM card still displays the signal intensity of the second SIM card because the second SIM card is in a network signal state; in the communication process of the first SIM card, as the terminal moves the second SIM card to be disconnected, the working mode of the system UI is switched from the DSDA mode to the DSDS mode, and the system UI controls the display icon of the second SIM card to be switched from the display signal intensity to the display funnel icon, so that a user cannot perceive that the second SIM card is disconnected, and the user experience is improved.

The points to be described here are: the mode of the Modem for switching the operation mode of the systemUI from the DSDA mode to the DSDS mode is to enable the systemUI to switch the display rule of the second SIM card, and the Modem is still in the DSDA mode, so that the Modem can search the network of the second SIM card in the communication process of the first SIM card. In the icon display control method shown in fig. 11, in a scenario in which the display rule of the systemUI according to the DSDS mode is added to the icon display control method shown in fig. 10, the Modem may continue to search for the second SIM card, as shown in step S43. After determining that the network of the second SIM card is restored, the Modem performs step S44 to switch the operation mode of the systemUI from the DSDS mode to the DSDA mode, where the network restoration of the second SIM card may be that the second SIM card is switched from the off-network state to the network signal state, and when the second SIM card searches for a cell supporting the DSDA mode related to the first SIM card supported by the terminal, the second SIM card is in the network signal state. The systemUI performs step S45, and displays the DSDA according to the display rule of the DSDA mode: and when the service state is the service state, the signal icon of the second SIM card displays the signal intensity and the operator name of the second SIM card, and the signal intensity and the operator name of the second SIM card can be reported when the working mode of the sustomUI is switched to the DSDA mode, so that the signal icon of the second SIM card can display the latest and real network signal state of the second SIM card, the display of the signal icon of the second SIM card is the same as the network signal state of the second SIM card, and the user experience is improved.

In some examples, after the operation mode of the systemUI is switched from the DSDA mode to the DSDS mode, the systemUI may be maintained in the DSDS mode until the call of the first SIM card is ended, and actively switched to the DSDA mode after the call of the first SIM card is ended, and displayed according to a display rule of the DSDA mode. One way in which the systemUI is displayed according to the DSDA mode display rules is: the system may refer to the manner of ending freezing shown in fig. 7 and fig. 8, wherein the signal icon of the second SIM card displays the signal intensity and the operator name before switching to the DSDS mode, and if the system ui receives the actively reported service state, signal intensity and operator name of the second SIM card before the timer times out, the signal icon of the second SIM card is displayed according to the reported signal intensity and operator name; if the service state, the signal strength and the operator name of the second SIM card are not received before the timer is overtime, the systemUI starts an active inquiry once, and the signal icon of the second SIM card is displayed according to the inquiry result, so that the systemUI can timely acquire the latest network signal state of the second SIM card, and the possibility of missing the network signal state of the second SIM card is reduced while the signal icon of the second SIM card is smoothly transited from the display funnel icon to the display of the signal strength and the operator name.

In some embodiments of the present application, the terminal may preset network configuration information supporting DSDA in the Modem, where the network configuration information supporting DSDA includes at least one of a combination of modes supporting DSDA and a combination of frequency bands under a mode supporting DSDA, and then the Modem may preferentially measure and search all the combinations of modes supporting DSDA and the combination of frequency bands under the mode supporting DSDA in a round of call process of the first SIM card, so that the Modem may search a cell where the second SIM card can reside as soon as possible, reduce a possibility that the second SIM card drops the network, and may recover the network as soon as possible after the network drops. The preferential measurement and search of all the combination of the systems supporting DSDA and the combination of the frequency bands under the system supporting DSDA means that: all the measurement and search of the combination of the systems supporting the DSDA and the combination of the frequency bands in the system supporting the DSDA are earlier than the combination of the systems supporting the DSDS and the combination of the frequency bands in the system supporting the DSDS.

If the first SIM card is in the communication process, the Modem preferentially measures the supported DSDA system combination and the frequency band combination under the DSDA system combination, so that the terminal is triggered to preferentially move to a cell supporting the DSDA system or the frequency band in the moving process, and the network drop of the second SIM card is reduced. The supported system combination of the DSDA can be a system combination related to the first SIM card, and is determined by a system corresponding to a cell where the first SIM card resides; if the second SIM card drops in the communication process of the first SIM card, the Modem can search the standard combination supporting the DSDA mode related to the first SIM card and the frequency band combination under the standard combination supporting the DSDA mode related to the first SIM card preferentially, so that the second SIM card can recover the network as soon as possible.

As shown in tables 1 and 2, table 1 shows a combination of modes supporting DSDA, table 1 also shows a combination of modes supporting DSDS, and table 2 shows a combination of frequency bands in a combination of modes supporting DSDA.

Table 1 System combinations supporting DSDA

INDEX	Double-card	RAT1	RAT2
				1	DSDA	NR	NR
2	DSDA	NR	LTE
				3	DSDS	LTE	LTE
4	DSDS	NR/LTE	GSM/WCDMA

Table 2 frequency band combinations under DSDA supported standard combinations

INDEX	RAT1	FREQ1	RAT2	FREQ2
					1	NR	NARFCN1	NR	NARFCN2
2	NR	NARFCN1	NR	NARFCN3
					3	NR	NARFCN1	LTE	EARFCN1
4	。。。	。。。	。。。	。。。

An example is where a first SIM card resides in a cell of an NR and the terminal communicates through the first SIM card. Referring to table 1, the standard combination of DSDA related to the first SIM card includes: NR and NR, NR and LTE, the Modem may preferentially measure and search in the NR and LTE modes, and preferentially measure and search the frequency bands shown in Table 2 in the NR and LTE modes.

An example, a first SIM card resides in a cell of LTE and a terminal communicates through the first SIM card. Referring to table 1, the combination of the modes of the DSDA related to the first SIM card is one of NR and LTE, and since the first SIM card resides on LTE, the Modem can preferentially measure and search in the NR mode, where the frequency bands shown in table 2 are preferentially measured and searched.

Fig. 12 shows a network searching process of the second SIM card in the first SIM card communication process, which may include the following steps:

s50, the network equipment transmits measurement configuration information to a Modem of the terminal, wherein the measurement configuration information can comprise at least one frequency point, and for example, the measurement configuration information can comprise a plurality of frequency points under 4G and a plurality of frequency points under 5G.

S51, when the Modem inquires that the network configuration information related to the first SIM card and supporting the DSDA contains the frequency points in the measurement configuration information, which are contained in the network configuration information related to the first SIM card and supporting the DSDA, are preferentially measured. For convenience of description, the frequency points in the measurement configuration information, which are included in the network configuration information supporting DSDA related to the first SIM card, are simply referred to as first type frequency points, the frequency points in the measurement configuration information, which are not included in the network configuration information supporting DSDA, are simply referred to as second type frequency points, and preferentially measuring the first type frequency points means that measurement of the first type frequency points is earlier than measurement of the second type frequency points.

The frequency point in the measurement configuration information included in the network configuration information supporting DSDA related to the first SIM card may be that if the network configuration information supporting DSDA related to the first SIM card includes a combination of standards supporting DSDA, when the standard to which the frequency point in the measurement configuration information belongs is the standard in the combination of standards supporting DSDA, the frequency point in the measurement configuration information included in the network configuration information supporting DSDA related to the first SIM card is determined. As described in table 1 above, the first SIM card resides in the NR cell, and the terminal communicates through the first SIM card. Referring to table 1, the standard combination of DSDA related to the first SIM card includes: and if the frequency points in the measurement configuration information belong to the frequency points in the NR or LTE system, determining that the network configuration information which is related to the first SIM card and supports DSDA contains the frequency points in the measurement configuration information. An example, a first SIM card resides in a cell of LTE and a terminal communicates through the first SIM card. Referring to table 1, the standard combination of DSDA related to the first SIM card is one combination of NR and LTE, because the first SIM card resides on LTE, if the frequency point in the measurement configuration information belongs to the frequency point in the NR standard, it is determined that the network configuration information supporting DSDA related to the first SIM card includes the frequency point in the measurement configuration information.

If the network configuration information supporting DSDA related to the first SIM card comprises a frequency band combination under the system combination supporting DSDA, determining that the network configuration information supporting DSDA related to the first SIM card comprises the frequency point in the measurement configuration information when the frequency point in the measurement configuration information is the frequency point in the frequency band combination under the system combination supporting DSDA. As described in conjunction with table 1 and table 2 above, the first SIM card resides in the NR cell, and the terminal communicates through the first SIM card. Referring to table 1, the standard combination of DSDA related to the first SIM card includes: NR and NR, NR and LTE; the frequency points under NR format are specified in table 2 to include: NARFCN1, NARFCN2 and NARFCN3, the frequency points under the LTE system are designated to comprise EARFCN1; and if the frequency point in the measurement configuration information corresponds to the designated frequency point, determining that the network configuration information supporting DSDA related to the first SIM card contains the frequency point in the measurement configuration information.

S52, the Modem sends a measurement report to the network equipment, wherein the measurement report can carry the cell information of the frequency point of the preferential measurement, such as the signal strength of the cell.

And S53, the network equipment sends a switching command to the Modem. The switching command carries the cell identifier of the frequency point of the priority measurement, and the signal strength of the cell of the frequency point of the priority measurement meets the cell switching condition, so that the second SIM card can reside on the cell of the frequency point of the priority measurement.

S54, the Modem controls the second SIM card to be switched to the cell of the frequency point of the preferential measurement. Because the cell of the frequency point of the priority measurement, to which the Modem is switched, supports the DSDA, in the process of the first SIM card communication, the second SIM card can reside in the cell of the frequency point of the support of the DSDA, the second SIM card maintains a network-resident state, and the resident cell corresponds to a service state, signal strength and an operator name and is reported to the systemUI.

The step S30 in fig. 9, the step S40 in fig. 10, and the step S43 in fig. 11 may complete the step of searching for the network by using the second SIM card from step S50 to step S54. And when the second SIM card is switched to the cell with the frequency point which is preferentially measured, the second SIM card is in a network signal state, and the Modem can send the service state, the signal strength and the operator name of the second SIM card to the system UI through RIL and telephone, and the system UI controls the signal icon of the second SIM card to display the signal strength of the second SIM card. When the Modem searches that the network is in the network-down state, the terminal may refer to the icon display control method shown in fig. 4 to 11 for processing, which is not described herein. In addition, in some examples, the Modem and the systemUI may interact through a telephenyl, omitting the link of RIL forwarding; in some examples, the Modem may interact directly with the systemUI, and the present embodiment does not limit the interaction process between the Modem and the systemUI.

In some implementations, the icon display control method is applied to a terminal, which may be a mobile phone, a tablet computer, a desktop computer, a laptop computer, a notebook computer, an Ultra-mobile Personal Computer (UMPC), a handheld computer, a netbook, a personal digital assistant (Personal Digital Assistant, PDA), a wearable electronic device, a smart watch, or the like. The specific form of the electronic device is not particularly limited in the present application.

The structure of the terminal is as shown in fig. 13, and may include: the device comprises a processor, an external memory interface, an internal memory, a universal serial bus (Universal Serial Bus, USB) interface, a charging management module, a power management module, a battery, an antenna 1, an antenna 2, a mobile communication module, a wireless communication module, a sensor module, keys, a motor, an indicator, a camera, a display screen, a SIM card slot and the like. Wherein the audio module may include a speaker, a receiver, a microphone, an earphone interface, etc., and the sensor module may include a pressure sensor, a gyro sensor, a barometric sensor, a magnetic sensor, an acceleration sensor, a distance sensor, a proximity sensor, a fingerprint sensor, a temperature sensor, a touch sensor, an ambient light sensor, a bone conduction sensor, etc.

It should be understood that the structure illustrated in the embodiments of the present application does not constitute a specific limitation on the terminal. In other embodiments, the terminal may include more or fewer components than shown, or certain components may be combined, or certain components may be split, or different arrangements of components. The illustrated components may be implemented in hardware, software, or a combination of software and hardware.

Wherein the processor may comprise one or more processing units, such as: the processors may include application processors (Application Processor, AP), modem processors, graphics processors (Graphics Processing Unit, GPU), image signal processors (Image Signal Processor, ISP), controllers, video codecs, digital signal processors (Digital Signal Processor, DSP), baseband processors, and/or Neural network processors (Neural-network Processing Unit, NPU), etc. Wherein the different processing units may be separate devices or may be integrated in one or more processors. The processor is a nerve center and a command center of the terminal, and the controller can generate operation control signals according to the instruction operation codes and the time sequence signals to finish the control of instruction fetching and instruction execution.

The external memory interface may be used to connect an external memory card, such as a Micro SD card, to extend the memory capabilities of the terminal. The external memory card communicates with the processor through an external memory interface to realize the data storage function. The internal memory may be used to store computer-executable program code that includes instructions. The processor executes the instructions stored in the internal memory to perform various functional applications of the terminal and data processing. For example, in the embodiment of the present application, the processor causes the terminal to execute the icon display control method provided by the embodiment of the present application by executing the instruction stored in the internal memory.

The wireless communication function of the terminal can be realized by an antenna 1, an antenna 2, a mobile communication module, a wireless communication module, a modem processor, a baseband processor and the like. In some embodiments, the antenna 1 and the mobile communication module of the terminal are coupled, and the antenna 2 and the wireless communication module are coupled, so that the terminal can communicate with a network and other devices through wireless communication technology. The wireless communication techniques may include the Global System for Mobile communications (global system for mobile communications, GSM), general packet radio service (general packet radio service, GPRS), code division multiple access (code division multiple access, CDMA), wideband 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, among others. The GNSS may include a global satellite positioning system (global positioning system, GPS), a global navigation satellite system (global navigation satellite system, GLONASS), a beidou satellite navigation system (beidou navigation satellite system, BDS), a quasi zenith satellite system (quasi-zenith satellite system, QZSS) and/or a satellite based augmentation system (satellite based augmentation systems, SBAS).

The display screen is used to display images, videos, a series of graphical user interfaces (Graphical User Interface, GUI) etc., such as display of signal icons etc. The display screen includes a display panel. The display panel may employ a liquid crystal display (liquid crystal display, LCD), an organic light-emitting diode (OLED), an active-matrix organic light-emitting diode (AMOLED) or an active-matrix organic light-emitting diode (matrix organic light emitting diode), a flexible light-emitting diode (flex), a mini, a Micro-led, a quantum dot light-emitting diode (quantum dot light emitting diodes, QLED), or the like. In some embodiments, the terminal may include 1 or N displays, N being a positive integer greater than 1.

The SIM card slot is used for inserting the SIM card or extracting the SIM card from the SIM card slot, so as to realize contact and separation with the terminal. The terminal can support 2 or N SIM card slots, and N is a positive integer greater than 2. The SIM card slot can support Nano SIM cards, micro SIM cards, SIM cards and the like. The terminal interacts with the network through the SIM card to realize the functions of communication, data communication and the like. In some embodiments, the terminal employs esims, i.e.: an embedded SIM card. The eSIM card can be embedded in the terminal and cannot be separated from the terminal. In some embodiments of the present application, the terminal may support 2 SIM card slots so that the terminal may insert two SIM cards.

In addition, an operating system is run on the components. Such as the iOS operating system developed by apple corporation, the Android open source operating system developed by google corporation, the Windows operating system developed by microsoft corporation, etc. An operating application may be installed on the operating system.

The operating system of the terminal may employ a layered architecture, an event driven architecture, a micro-core architecture, a micro-service architecture, or a cloud architecture. In the embodiment of the application, an Android system with a layered architecture is taken as an example, and the software structure of a terminal is illustrated. Fig. 14 is a software configuration block diagram of the terminal. The software structure adopts a layered architecture, the layered architecture divides the software into a plurality of layers, and each layer has clear roles and division work. The layers communicate with each other through a software interface. Taking an Android system as an example, the Android system runs on an AP, in some embodiments, the Android system is divided into five layers, namely an application layer, an application Framework layer (Framework), a An Zhuoyun row (Android run) and system library, a Hardware Abstraction Layer (HAL) and a system Kernel layer (Kernel).

The application layer may include a series of application packages, among other things. The application package may include a camera, a gallery, a calendar, a call, a map, a WLAN, bluetooth, music, video, a short message, etc. APP, and the application layer may further include a systemUI (system UI) for displaying an interface of the terminal, such as displaying a signal icon corresponding to the SIM card, displaying a call interface, etc. The application framework layer provides an application programming interface (Application Programming Interface, API) and programming framework for application programs of the application layer. The application framework layer includes a number of predefined functions. For example, the application framework layer may include a window manager, a content provider, a view system, a telephony manager, a resource manager, a notification manager, and the like. The telephony manager is used to provide telephony functions of the terminal, such as management of the call state (including on, off, etc.), and is represented in fig. 4 by a telephone. The application framework layer may also include an RIL (Radio Interface Layer, wireless communication interface layer) through which the Modem may interact with the telephenyl.

Android run time includes a core library and virtual machines. Android run time is responsible for scheduling and management of the Android system.

The core library consists of two parts: one part is a function which needs to be called by java language, and the other part is a core library of android.

The application layer and the application framework layer run in a virtual machine. The virtual machine executes java files of the application program layer and the application program framework layer as binary files. The virtual machine is used for executing the functions of object life cycle management, stack management, thread management, security and exception management, garbage collection and the like.

The system library may include a plurality of functional modules. For example: surface manager (surface manager), media Libraries (Media Libraries), three-dimensional graphics processing Libraries (e.g., openGL ES), 2D graphics engines (e.g., SGL), etc.

The HAL may contain a plurality of library modules, each of which may implement a set of interfaces for a particular type of hardware component, such as HALs including display HAL, camera HAL, audio HAL, sensor HAL, and the like. The kernel layer is a layer between hardware and software. The inner core layer at least comprises a display driver, a camera driver, an audio driver and a sensor driver.

In some embodiments of the present application, a Modem (Modem) in the terminal may report network signal information related to the SIM card to the AP, where the network signal information may include a service state, where the service state includes a service state and a no-service state, and the service state is used to indicate that there is a network signal; the out-of-service state is used to indicate that there is no network signal. The network signal information may also include signal strength and operator name when the service status is a serviced status. The network signal information can be acquired by the Modem, and is transferred to the application program layer through the kernel layer, the HAL, the system library and the application program framework layer, and a signal icon corresponding to the network signal information is displayed through the system UI in the application program layer.

Furthermore, some embodiments of the present application provide a terminal comprising: one or more processors and memory; the memory is used for storing computer program codes, the computer program codes comprise computer instructions, and when one or more processors execute the computer instructions, the terminal executes the icon display control method.

Some embodiments of the application provide a readable computer storage medium comprising computer instructions that, when run on a terminal, cause a processor in the terminal to perform the above-described icon display control method.

Some embodiments of the present application provide a chip system applied to a terminal, where the chip system includes at least one processor and an interface, and the interface is configured to receive an instruction and transmit the instruction to the at least one processor; the at least one processor executes instructions to cause the terminal to perform the icon display control method described above. In some examples, the at least one processor executes instructions that cause the terminal to perform the steps of: under the scene that the terminal currently works in a DSDA mode, a first SIM card of the terminal resides in a cell of a first network system supported by the DSDA mode and the first SIM card is in a round of call: if the second SIM card of the terminal is currently in a preset first scene, displaying a signal icon of the second SIM card as a first signal icon, wherein the first signal icon is used for indicating that both the data service and the voice service of the second SIM card are in an available state; if the second SIM card is currently in a preset second scene, the signal icon of the second SIM card is displayed as a second signal icon, the second signal icon is used for indicating that both the data service and the voice service of the second SIM card are in an unavailable state, and the preset second scene indicates that the second SIM card is in a network-free state but the second signal icon is different from the corresponding signal icon when the SIM card is in the network-free state.

In one possible implementation, the at least one processor includes a first processor and a second processor, where the first processor is configured to determine whether the second SIM card is in a preset first scene or in a preset second scene; the second processor is used for controlling the signal icon of the second SIM card to be displayed as a first signal icon if the second SIM card of the terminal is currently in a preset first scene; and if the second SIM card is currently in the preset second scene, controlling the signal icon of the second SIM card to be displayed as a second signal icon.

In one possible implementation, the first processor is a modem processor and the second processor is an application processor.

Claims (18)

1. An icon display control method, characterized in that it is applied to a terminal having two SIM card slots, and in the case where the two SIM card slots are respectively inserted into a first SIM card and a second SIM card, the method includes:

under the scene that the terminal currently works in a DSDA mode, the first SIM card resides in a cell of a first network system supported by the DSDA mode, and the first SIM card is in a round of call:

if the second SIM card is currently in a preset first scene, displaying a signal icon of the second SIM card as a first signal icon, wherein the first signal icon is used for indicating that both the data service and the voice service of the second SIM card are in an available state;

If the second SIM card is currently in a preset second scenario, the signal icon of the second SIM card is displayed as a second signal icon, where the second signal icon is used to indicate that both the data service and the voice service of the second SIM card are in an unavailable state, and the preset second scenario indicates that the second SIM card is in a network-free state but that the signal icon corresponding to the second signal icon is different from the signal icon corresponding to the SIM card when the second signal icon is in the network-free state.

2. The method according to claim 1, wherein the method further comprises: and under the condition that the terminal is currently operated in a DSDA or DSDS mode and the first SIM card is not in communication, if the second SIM card is currently in a preset second scene, displaying the signal icon of the second SIM card as the same as the corresponding signal icon when the SIM card is in a network-free state.

3. The method according to claim 1 or 2, characterized in that the method further comprises: and displaying the signal icon of the second SIM card to be the same as the second signal icon under the scene that the terminal is currently operated in a DSDS mode and the first SIM card is in a round of conversation.

4. The method according to any one of claims 1 to 3, wherein the preset first scenario includes any one of a first cell in which the second SIM card resides and a second cell in which the second SIM card resides, wherein the first cell is a cell supporting a second network system of the DSDA mode, the first network system and the second network system are one of a combination of systems of the DSDA mode supported by the terminal, wherein the second cell is a cell corresponding to a first frequency band supporting the DSDA mode in the second network system, and the first SIM card resides in a cell corresponding to a second frequency band of the first network system, and the first frequency band and the second frequency band are one of a combination of frequency bands supporting the DSDA mode corresponding to a combination of the DSDA mode supported by the terminal;

And/or

The preset second scene comprises any one of a non-service area where the terminal is currently located in the second SIM card, a cell coverage where the terminal is currently located in a system combination which does not support a DSDA mode, and a cell coverage where the terminal is currently located in a system combination which supports the DSDA mode but not in a frequency band combination which supports the DSDA mode.

5. The method of any one of claims 1 to 4, wherein the second signal icon is a funnel icon and the signal icon corresponding to the SIM card in the network-free state is a band x icon.

6. The method according to any one of claims 1 to 5, further comprising: and continuously displaying the signal icon of the second SIM card as the second signal icon under the condition that the second SIM card is continuously positioned in the preset second scene.

7. The method according to any one of claims 1 to 6, further comprising: after the first SIM card is finished, the signal icon of the second SIM card is switched from displaying the second signal icon to displaying a third signal icon, wherein the third signal icon is used for indicating that the data service and the voice service of the second SIM card are in the available states.

8. The method of claim 7, wherein the method further comprises: after the signal icon of the second SIM card is switched from displaying the second signal icon to displaying the third signal icon, acquiring network signal information searched by the second SIM card after the first SIM call is ended;

and switching the signal icon of the second SIM card from displaying the third signal icon to displaying a fourth signal icon, wherein the fourth signal icon corresponds to the acquired network signal information searched by the second SIM card.

9. The method of claim 8, wherein after the signal icon of the second SIM card is switched from displaying the second signal icon to displaying the third signal icon, the obtaining network signal information searched by the second SIM card after the first SIM call is ended includes:

if the system UI in the terminal receives the first network signal information of the second SIM card reported by the modem processor in the terminal before the timer in the terminal is overtime, the first network signal information of the second SIM card is used as the network signal information searched by the second SIM card;

If the system UI in the terminal does not receive the network signal information of the second SIM card reported by the modem processor in the terminal before the timer in the terminal is overtime, the system UI sends a second SIM card network information inquiry request to the modem processor, the modem processor sends the second network signal information of the second SIM card to the system UI, and the second network signal information of the second SIM card is the network signal information searched by the second SIM card.

10. The method according to any one of claims 1 to 9, wherein if the second SIM card is currently in a preset second scenario, displaying the signal icon of the second SIM card as a second signal icon includes: if the second SIM card is currently in a preset second scene, the terminal is switched from working in the DSDA mode to working in the DSDS mode;

and controlling the signal icon of the second SIM card to be displayed as the second signal icon according to the fact that the terminal works in the DSDS mode.

11. The method of claim 10, wherein the switching of the terminal operation in the DSDA mode to operation in the DSDS mode comprises: and the system UI in the terminal is switched from the DSDA mode to the DSDS mode, and is used for controlling the display of the signal icon of the second SIM card.

12. The method according to any one of claims 1 to 11, further comprising: presetting network configuration information supporting the DSDA mode, wherein the network configuration information comprises a system combination supporting the DSDA mode and/or a frequency band combination under a system supporting the DSDA mode;

selecting target network configuration information from preset network configuration information supporting the DSDA mode according to the first network system, wherein the target network configuration information is network configuration information supporting the DSDA mode, which is selected according to the first network system and related to a first SIM card;

receiving measurement configuration information sent by network equipment, wherein the measurement configuration information comprises a first frequency point and a second frequency point;

if the first frequency point in the measurement configuration information belongs to the frequency point of the second network system in the target network configuration information, preferentially measuring the first frequency point;

and when the signal strength of the first frequency point meets the cell switching condition, the second SIM card resides in a cell corresponding to the first frequency point under the second network system.

13. The method according to any one of claims 1 to 12, further comprising at least one of:

The second SIM card resides in a cell of a second network system supported by the DSDA mode;

the first network system is a 4G system, and the frequency band corresponding to the cell of the first network system is at least one frequency band specified by a 4G protocol; or the first network system is a 5G system, and the frequency band corresponding to the cell of the first network system is at least one frequency band specified by a 5G protocol;

or alternatively, the first and second heat exchangers may be,

the second network system is a 4G system, and the frequency band corresponding to the cell of the second network system is at least one frequency band specified by a 4G protocol; or the second network system is a 5G system, and the frequency band corresponding to the cell of the second network system is at least one frequency band specified by a 5G protocol.

14. A terminal, comprising:

one or more processors and memory;

the memory is configured to store computer program code comprising computer instructions that, when executed by the one or more processors, perform the icon display control method of any one of claims 1 to 13.

15. A readable computer storage medium comprising computer instructions which, when run on a terminal, cause a processor in the terminal to perform the icon display control method of any of claims 1 to 13.

16. A chip system applied to a terminal, wherein the chip system comprises at least one processor and an interface, wherein the interface is used for receiving instructions and transmitting the instructions to the at least one processor; the at least one processor executing the instructions causes the terminal to perform the steps of:

under the scene that a terminal currently works in a DSDA mode, a first SIM card of the terminal resides in a cell of a first network system supported by the DSDA mode, and the first SIM card is in a round of call:

if the second SIM card of the terminal is currently in a preset first scene, displaying a signal icon of the second SIM card as a first signal icon, wherein the first signal icon is used for indicating that both data service and voice service of the second SIM card are in an available state;

if the second SIM card is currently in a preset second scenario, the signal icon of the second SIM card is displayed as a second signal icon, where the second signal icon is used to indicate that both the data service and the voice service of the second SIM card are in an unavailable state, and the preset second scenario indicates that the second SIM card is in a network-free state but that the signal icon corresponding to the second signal icon is different from the signal icon corresponding to the SIM card when the second signal icon is in the network-free state.

17. The chip system of claim 16, wherein the at least one processor comprises a first processor and a second processor, the first processor configured to determine whether the second SIM card is in the preset first scenario or in the preset second scenario;

the second processor is configured to control a signal icon of a second SIM card of the terminal to be displayed as a first signal icon if the second SIM card is currently in a preset first scene; and if the second SIM card is currently in a preset second scene, controlling the signal icon of the second SIM card to be displayed as a second signal icon.

18. The system on a chip of claim 17, wherein the first processor is a modem processor and the second processor is an application processor.