TW201105160A - Method for realizing a mobile phone of dual numbers and dual standby with a single CDMA chip - Google Patents

Abstract

The present invention provides a method for realizing a mobile phone of dual phone numbers and dual standby with a single CDMA chip. The method applies to a CDMA mobile phone. The CDMA mobile phone includes a RUIM card with the corresponding user's number. The method includes: burning the data of user's another common number to the CDMA mobile phone as fuselage number and realizing dual numbers; reading the information of RUIM card and fuselage number and searching network; respectively recording and storing the paging parameters of the RUIM card and fuselage number; controlling the RUIM card and fuselage number to launch network register to the network; determining whether the paging frequency point of the RUIM card and fuselage number are same; if aging frequency point of the RUIM card and fuselage number are same, then executing the method of same frequency point; otherwise, executing the method of different frequency point.

Description

201105160 VI. Description of the Invention: [Technical Field] The present invention relates to a method for implementing a dual CDMA (code division multiple, access, code division multiple access) dual dual standby handset. [Prior Art] Mobile communication has developed rapidly, and more and more users have more than one number, that is, corresponding to two or more Removable User Identity Modules (hereinafter referred to as RUIM) cards. In this case, the user can choose to use two mobile phones, but this is very troublesome, so more and more users choose to use a dual-relay dual-standby mobile phone. At present, there are two mobile phones with dual RUIM cards implemented by two sets of CDMA chips. Each set of chips runs its own protocol stack to support a single RUIM card. It can realize that both numbers are in standby state at the same time, and any one can call out and call in. However, the dual RUIM card dual standby mobile phone using two sets of CDMA chips undoubtedly increases the size and cost of the mobile phone. In addition, support for dual RUI1V [card dual standby mobile phone requires two card holders, so that users can insert two RUIM cards, have two numbers, this dual-number dual standby implementation also increases the hardware of the phone Cost and volume. [Invention] In view of the above, it is necessary to provide a method for implementing a single CDMA chip dual-number dual standby mobile phone, which realizes a single CDMA chip dual-number dual standby mobile phone by burning a RUIM card. A method for implementing a dual CDMA dual-standby mobile phone of a single CDMA chip, the party 201105160 method running on a CDMA mobile phone, the CDMA mobile phone comprising a hardware driver layer, a link layer, a high-level service processing layer and a RUIM card, the RUIM. The card corresponds to a user number, and the CDMA mobile phone further includes a burning software. The method includes: starting the CDMA mobile phone to perform system initialization; and burning the data information of another common number of the user into the CDMA mobile phone by using the burning software, as The body number enables the CDMA mobile phone to implement the double number; the hardware driver layer separately reads the information of the RUIM card and the body number; β according to the paging parameters of the RUIM card and the body number, the hardware driver layer follows the normal CDMA The protocol flow searches the network, and the paging parameters include a paging frequency, a paging channel, and a paging time slot; the high-level service processing layer separately records and stores the paging parameters of the RUIM card and the body number; the high-level service processing layer Control the RUIM card and the body number to initiate network registration to the network, complete the network registration of the RUIM card and the body number; the high-level service processing layer determines the paging of the RUIM card and the body number Whether the points are the same; if the paging frequency of the RUIM card and the body number is the same, the same frequency double standby φ method is executed; if the paging frequency of the RUIM card and the body number is not the same, the inter-frequency dual standby is performed method. Compared with the prior art, the present invention provides a method for implementing a dual CDMA dual-standby mobile phone with a single CDMA chip, which implements dual-number dual standby by burning a body number and adding a RUIM card number, since it only needs A RUIM card is installed, so the hardware structure is simpler than the dual RUIM card dual standby, and the volume is smaller, which also reduces the cost. [Embodiment] 5 201105160 As shown in Fig. 1, it is a system diagram of a dual CDMA dual standby mobile phone of the present invention. The single CDMA chip dual-number dual standby mobile phone 10 (hereinafter referred to as "CDMA mobile phone 1") includes a RUIM (Removable User Identity Module) card 100 and a burning software 101. The burning software 101 is configured to burn data information of another common number of the user into the mobile phone as the body number, so that the CDMA mobile phone 10 realizes the double number. The written data information mainly includes, but is not limited to, a) IMSI: "international mobile subscriber identity", abbreviation of "International Mobile Subscriber Identity", which is the only unique identification of mobile users worldwide; J; b) ESN (MEID) ) : ESN is the abbreviation of "electronic serial number", which is the identity of the mobile phone, and the MEID (mobile equipment identifier) is the only 56bit mobile terminal identification number in the world, because the ESN number is The limited resources are basically exhausted, so a 56-bit MEID number segment was created to replace the 32-bit ESN segment. The MEID is mainly assigned to the CDMA system type mobile phone; c) A-Key: also called the authentication key, which is the key stored in the MS (M mobile station) for authentication and encryption, and is the 64-bit data allocated to the MS. 'And only known to the MS and the associated home location register/authentication center (HLR/AC). For example, a RUI1V [card corresponds to a mobile phone number] writes data information of a corresponding number of a RUIM card provided by the operator into the CDMA mobile phone 10, as the body number, the body number can enter The network uses, and the double-numbered CDMA mobile phone 10 is realized by the body number and the RUIM card 100. As shown in FIG. 2, it is an architectural diagram of a preferred embodiment of the single CDMA chip dual-number dual standby mobile phone 201105160 of the present invention. The CDMA mobile phone 10 includes a hardware drive layer 1 (referred to as "L1 layer"), a link layer 2 (referred to as "L2 layer"), a high-level service layer 3 (referred to as "CP layer 3"), a user interface 4, The RUIM card service module 5 and the fuselage NV service module 6. The L2 layer is connected to the L1 layer and the CP layer 3, and data can be exchanged in both directions. The L1 layer is used to provide an interface between the chip of the CDMA mobile phone 10 and the application layer software, and the wireless communication between the internal chip of the CDMA mobile phone 10 and the application layer software is controlled, and the L1 layer can also be read. The information of the number corresponding to the RUIM card, and the read information refers to system-related information such as system parameters. The L2 layer is mainly used for transmitting data, receiving data, reading and writing operations, and performing authentication processing. The L2 layer includes a data packet transmitting unit 20, a data unpacking receiving unit 21, an authentication processing unit 22, and a read/write operation unit 23. The data packet sending unit 20 is configured to pack the service data processed by the CP layer 3 into a bit stream and send it to the infinite channel. The data unpacking receiving unit 21 is configured to receive the bit data stream sent by the wireless channel and parse it into service data. The authentication processing unit 22 is configured to perform related encryption processing on the RUIM card service module 5 and the airframe NV service module 6 through an authentication algorithm to ensure the security of the user service. The CP layer 3 is configured to process paging listening parameters including a set of CDMA chips for listening to the paging frequency, paging channel and paging time limit of the RUIM card 100 and the body number, and to the CDMA mobile phone. 10 wireless resources, mobility and supplementary services are managed. For example, the call, 201105160 SMS and other services are processed. When the CP layer 3 is operated on the RUIM card 100, part of the data in the RUIM card 100 can be operated. If the body number is operated, the CP layer 3 operates on the data related to the body number. The RUIM card service module 5 controls and operates the data on the RUIM card 100. Since the partially encrypted data is present in the RUIM card 100, the RUIM card service module 5 is required to read or write data. The airframe NV service module 6 is used for controlling and operating the body NV data; the body NV is a module for burning the data information of the number to the body for permanently storing the data information. The operation of the body NV data of the airframe NV service module 6 can read and write data, and can also perform complex operations related to authentication. The RUIM card service module 5 and the body NV service module 6 are respectively connected to the L1 layer and the L2 layer to implement dual-number dual standby of the CDMA mobile phone 10. It should be noted that the data information of another common φ number of the user is burned into the CDMA mobile phone 10 by the burning software 101 to form a body number, and the CDMA mobile phone 10 realizes the double number. When the CP layer 3 processes the service, it will judge the number to be operated. If the number is the number of the RUIM card 100, the data of the RUIM card 100 is directly subjected to an authentication process or a read operation; if the number is a body number, During the read and write operation, the NV service module 6 is directly read and written by the body. When the operation is performed, the information of the body number is transmitted to the processing unit 22 for encryption processing, and the data operated by the device is the body NV. Provided by the service module 6, after the processing is completed, it is transmitted to the CP layer 3 through the authentication processing unit 22. For the data received by the 201105160 L1 layer, it is necessary to determine whether the number is the body number or the corresponding number of the RUIM card 100, and then transmit it to the corresponding service module for processing. As shown in FIG. 3, it is a flowchart of a preferred embodiment of a method for implementing a dual CDMA dual standby mobile phone of the present invention. In step S10, the CDMA mobile phone 10 is powered on to perform system initialization. In step S11, the data information of another common number of the user is burned into the CDMA mobile phone 10 by the burning software, and the CDMA mobile phone 10 is double-sized as the body number. In step S12, the L1 layer reads the information of the RUIM card 100 and the body number, respectively. In step S13, the L1 layer uses the paging parameters of the RUIM card 100 and the body number respectively and searches the network according to the normal CDMA protocol flow, and the paging parameters include a paging frequency point, a paging channel, and a paging time slot. In step S14, the CP layer 3 reads the φ pin message of the system of the CDMA mobile phone 10, and records and saves the paging parameters of the RUIM card 100 and the body number, respectively. In step S15, the CP layer 3 controls the RUIM card 100 and the body number to initiate network registration to the network, and completes the network registration of the RUIM card 100 and the body number. In step S16, the CP layer 3 determines whether the paging frequency points of the RUIM card 100 and the body number are the same. In step S17, if the paging frequency of the RUIM card 100 and the body number are the same, the co-frequency point dual standby method is performed (see Fig. 4). 201105160 Step S19, if the paging frequency of the RUIM card 100 and the body number are not the same, the inter-frequency dual-standby method is performed (see FIG. 5). As shown in FIG. 4, it is a detailed flowchart of the step S17 co-frequency point dual standby method in FIG. In step S170, the CP layer 3 determines whether the paging slots of the RUIM card 100 and the body number are the same, and the paging slot refers to the value of the paging slot on-time period in a normal sense. If the paging slots of the RUIM card 100 and the body number are not the same, step S171 is performed; if the paging slots of the RUIM card 100 and the body number are the same, step S177 is performed. In step S171, the L3 layer compares the paging slots of the RUIM card 100 and the body number to the front, and the CP layer 3 configures the RUIM card 100 and the slot number of the body number on the paging slot to the L1 layer. Step S172, the CP layer 3 notifies the L1 layer to enter a sleep state, for example, can send a sleep parameter (for example, L1_SLEEP_M, L1_REACQ_R) to the L1 layer to make the L1 layer sleep state, and the L1 layer calculates the next time according to the time slot parameter φ. Wake up, that is, calculate the time of the next wake-up, and then enter the sleep state; once the wake-up time arrives, that is, when the L1 layer is awakened, the L1 layer receives the L2 layer data unpacking receiving unit 21 from the paging channel. The paging message is sent and the paging message is sent to the CP layer 3. In step S217, the CP layer 3 matches the paging message transmitted by the L1 layer with the RUIM card 100 or the body number. In step S174, the CP layer 3 determines whether the paging message matches the information of the RUIM card 100. Step S175, if the paging message matches the information of the RUIM card 100 not 201105160, the CP layer 3 determines whether the paging message matches the information of the body number. If the paging message does not match the information of the body number, the process returns to step S171. In the above steps S174 and S175, if the paging message matches any of the information in the RUIM card 100 or the body number, the flow proceeds to step S176. Step S176, in response to the paging message, that is, the matching RUIM card 100 or the body number initiates a response to the network. In step S177, the CP layer 3 configures the slot parameters of the RUIM card 100 to the L1 layer. In step S178, the CP layer 3 notifies the L1 layer to enter a sleep state, and the L1 layer calculates the time of the next wake-up according to the time slot parameter. When the wake-up is awakened, the L1 layer receives the paging message and transmits the message to the CP layer 3. In step S179, the CP layer 3 matches the paging message sent by the L1 layer to the RUIM card 100. In step S180, the CP layer 3 determines whether the paging message matches the information of the RUIM card 100 φ. Step S181, if the paging message does not match the information of the RUIM card 100, the CP layer 3 determines whether the paging message matches the information of the body number. If the paging message does not match the information of the body number, the process returns to step S179. In the above steps S180 and S181, if the paging message matches any of the information in the RUIM card 100 or the body number, the flow proceeds to step S176. As shown in FIG. 5, it is a detailed flowchart of the step S19 multi-frequency point dual standby method in FIG. 11 201105160 Step S190, the CP layer 3 configures the RUIM card 100 and the slot number of the front fuselage number on the paging slot to the L1 layer. Step S191, the CP layer 3 notifies the L1 layer to enter a sleep state, and the L1 layer calculates the time of the next wake-up according to the time slot parameter, and when waking up, the L1 layer receives the paging message and sends the paging message to the CP. Layer 3. In step S192, the CP layer 3 matches the paging message sent by the L1 layer to the RUIM card 100. In step S193, the CP layer 3 determines whether the current paging frequency is the paging frequency of the RUIM card 100. If the current paging frequency is the paging frequency of the RUIM card 100, step S194 is performed; if the current paging frequency is not the paging frequency of the RUIM card 100, step S195 is performed. In step S194, the CP layer 3 determines whether the paging message matches the information of the RUIM card 100. If the paging message does not match the information of the RUIM card 100, step S197 is performed. In step S195, the CP layer 3 determines whether the paging message matches the φ information of the body number. If the paging message does not match the information of the body number, step S197 is performed. Step S196, in response to the paging message, that is, the matched RUIM card 100 or the body number initiates a response to the network. In step S197, the CP layer 3 configures the slot parameters of the RUIM card and the body number to the L1 layer, and the flow proceeds to step S191. In the above step S194 and step S195, if the paging message matches any of the RUIM card 100 or the body number, the flow directly proceeds to step S196. 12 201105160 In summary, the invention complies with the requirements of the invention patent, and proposes a patent application according to law. The above description is only the preferred embodiment of the present invention, and the scope of the present invention is not limited to the above-described embodiments, and those skilled in the art will be able to make equivalent modifications or variations in accordance with the spirit of the present invention. All should be covered by the following patent application. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a system diagram of a preferred embodiment of a dual CDMA dual standby handset of the present invention. * Figure 2 is a block diagram of a preferred embodiment of a dual CDMA dual standby handset of the present invention. 3 is a flow chart of a preferred embodiment of a method for implementing a dual CDMA dual standby handset in accordance with the present invention. Fig. 4 is a detailed flowchart of the step S17 of Fig. 3 using the same-frequency double standby method. Fig. 5 is a flow chart showing the φ refinement using the inter-frequency double-standby method in step S19 of Fig. 3. [Description of main component symbols] CDMA mobile phone 10 RUIM card 100 burning software 101 hardware drive layer 1 link layer 2 data packet transmission unit 20 data unpacking receiving unit 21 13 201105160 鐾 right processing unit 22 read and write operation unit 23 . Service processing layer 3 User interface 4 RUIM card service module 5 Body number service module 6 Power on, system initialization S10 I Burn another common number of the user into the CDMA mobile phone, read the RUIM card as the body number S11 And the body number information S12 According to the paging parameters of the RUIM card and the body number, search the network S13 according to the normal CDMA protocol flow and save the paging parameter S14 RUIM card and the body number of the RUIM card and the body number. The network registration S15 determines whether the paging frequency of the RUIM card and the body number is the same. • S16 The same frequency double standby method S17 The different frequency dual standby method S19 14

Claims (1)

201105160 VII. Patent application scope: 1. A method for implementing a dual CDMA dual-standby mobile phone with a single CDMA chip, the method running on a CDMA mobile phone, the CDMA mobile phone comprising a hardware driver layer, a link layer, and a high-level service processing layer And the RUIM card, the RUIM • card corresponds to a user number, and the CDMA mobile phone further includes a burning software. The method includes: starting the CDMA mobile phone and performing system initialization; burning the data information of another common number of the user by burning the software. In the CDMA mobile phone, as the body number, the CDMA mobile phone is implemented with a double number; the hardware driver layer separately reads the information of the RUIM card and the body number; according to the paging parameters of the RUIM card and the body number, The hardware driver layer searches the network according to a normal CDMA protocol process, and the paging parameters include a paging frequency point, a paging channel, and a paging time slot; the high-level service processing layer separately records and saves the RUIM card and the body number. Paging parameters; The high-level service processing layer controls the RUIM card and the body number to initiate network registration to the network, complete the network registration of the RUIM card and the body number; φ high The service processing layer determines whether the paging frequency of the RUIM card and the body number is the same; if the paging frequency of the RUIM card and the body number is the same, performing the same frequency dual standby method; and if the RUIM card and the body number are If the paging frequency is not the same, the inter-frequency dual-standby method is performed. 2. The method for implementing the same-frequency dual-standby method according to the method of claim 1, wherein the step of performing the same-frequency dual-standby method comprises: determining, by the high-level service processing layer, the RUIM card and the body number Whether the calling time slot is the same; if the paging time slot of the RUIM card and the body number is not the same, then 15 201105160 performs the step al-a6: al. ^ layer service processing layer configures the RUIM card and the body number on the paging slot The previous slot parameter is given to the hardware driver layer; • a2· The upper layer service processing layer notifies the hardware driver layer to enter the sleep state, and the hard layer calculates the time of the next wakeup, and when it is awakened, the hard drive layer Send the call message to the high-level service processing layer; a3. The two-layer service processing layer sends the hardware driver layer to the RUIM card or the body number to match; t'-, a4· high-level service processing layer determines the paging message and RmM If the match is not matched with the information of the RUIM card, then the high-level business department is equipped with the 'high-level business processing layer judgment; the suffocation v, the body-breaking signal is negative, and the match is not included. The number of information matches, then the upper level Processing said traffic control information body #u fj initiation response code does not match the code to the web, when the feed step & 1. "With the body of the hand, such as: Λ Λ Λ Λ 范 范 范 范 范 单 单 单 单 单 单 单 单 单 单 单 单 单 单 单 单 单 cd 单 cd cd cd cd cd cd cd cd cd cd cd cd cd cd cd In the step of whether the time slot is the same, the paging slot of the S Rum card and the body number is right u η. The high-level service office (4) performs the following steps (4) 6: moving layer;, $ _ setting the slot parameter of the RmM card to the hardware drive : move = spear = layer two hard two drive f3 will?? message sent to the high-level industry 'where', the hardware driver distribution processing layer will send the hard message layer to send the paging message to the high-level service processing layer to determine the paging message and The information of the curry card is 16 201105160 No match; b5. If the paging message matches the information of the RUIM card, the Gaoli layer controls the RUIM card to respond to the network, if the paging message does not match the information of the RUIM card , the high-level business processing layer determines whether the paging g ^ matches the information of the body number; "If the two batches of the paging message match the information of the body number, the high-level business processing control = the body number initiates a response to the network If the paging message does not match the information of the body number, the process returns The method for implementing the inter-frequency dual-standby method includes the step of performing the inter-frequency dual-standby method, as described in claim 1, wherein the step of performing the inter-frequency dual-standby method includes: configuring the RUIM card with the service processing layer. When the body number is paged, the time slot parameter before the crime is sent to the hardware driver layer; the gas layer processing layer notifies the hardware driver layer to enter the sleep state, and the time when the hardware will be awakened is awakened. Receive paging and send the message to the upper layer service processing layer; =3 to the layer service processing layer to distribute the hardware driver layer to the RUIM card, · ^ " layer service processing layer to determine whether the current paging frequency is RUIM If the current paging frequency is the paging frequency i of the RmM card = step S5_S6; if the current frequency of the hopping is not the calling frequency of the RUIM card, then steps S7-S8 are performed; The processing layer determines whether the paging message is matched with the Leica's asset δίΐ*, and the second::丨m ruim card matches the information, then the high-level service card + responds to the network, if the beer message and RUIM 贝 5 5 If the holes do not match, the flow goes to S9; [i layer service processing layer determines the paging If the information of the paging message matches the information of the body number, the upper layer controls the body number to respond to the network. If the information of the page disappears from the squid code does not match, Then, step S9 is performed; ~ one body 旎 59. The south layer service processing layer is allocated DΤΤΤΑ, the time slot parameter on the μ slot is given to the hardware driver layer 18