JP2017522762A - Using client-specific RGS to improve performance on multi-SIM and multi-RAT devices - Google Patents

Abstract

Various embodiments are implemented in a mobile communication device to maintain at least one separate RGS value for each of a plurality of RATs operating on a mobile communication device (e.g., a multi-RAT communication device). Provide a method. Specifically, a device processor (e.g., a crystal oscillator manager) on a mobile communication device can maintain a separate up-to-date RGS value for each of a plurality of RATs, Can be associated with RGS values. By storing each RGS value of multiple RATs, the device processor can determine the appropriate RGS value for each RAT, such as acquisition / re-acquisition operation, sleep scheduling calculation, and inter-handover / RAT measurement operation. It can be guaranteed to be used to facilitate. As a result, various embodiments can improve the performance of each RAT and the overall performance of the mobile communication device.

Description

Related ApplicationThis application is a U.S. Provisional Application No. 61 / 993,297 filed May 15, 2014, the entire content of which is incorporated herein by reference, named “Using Client-Specific RGS To Improve Performance on It claims the benefit of the priority of “Multi-SIM and Multi-RAT Devices”.

  Some new designs for mobile communication devices such as smartphones, tablet computers, and laptop computers allow two or more radio access technologies (`` RAT '') that allow devices to connect to two or more radio access networks. ")including. Examples of radio access networks include LTE, GSM (registered trademark), TD-SCDMA, CDMA2000, and WCDMA (registered trademark). Such mobile communication devices (sometimes referred to as "multi-RAT communication devices") are used to provide users with access to separate networks via two or more RATs. One or more radio frequency (RF) communication circuits or “RF resources” may also be included.

  A multi-RAT communication device is a mobile communication device with multiple SIM cards (i.e., a multi-subscriber identity module (SIM), each associated with a different RAT and utilizing different RF resources to connect to different mobile telephony networks. ), Multi-active or “MSMA” communication devices). A multi-RAT communication device can also include a multi-SIM multi-standby or “MSMS” communication device, each containing two or more SIM cards / subscriptions individually associated with separate RATs, each separate RAT Share one or more RF chains to communicate with multiple separate mobile telephony networks on behalf of a subscription. In addition, a multi-RAT communication device has one SIM card / subscription associated with two RATs that share a single shared RF resource to connect to two separate mobile networks instead of one subscription A single SIM communication device such as a single-radio LTE (“SRLTE”) communication device or a simultaneous GSM® + LTE (“SGLTE”) communication device.

  Conventional multi-RAT communication devices typically provide, among other things, a stable clock signal to the digital integrated circuit and a radio transmitter used by each RAT on the device to allow the RAT to communicate with the base station And a crystal oscillator used to stabilize the frequency of the radio receiver. When stabilizing the frequency, the multi-RAT communication device is generally referred to as the base station's natural deviation from the expected / standard frequency or timing of the base station (i.e., sometimes collectively referred to as the base station's "frequency error") ) To adjust the operating frequency of the crystal oscillator. For example, in response to determining the RAT base station frequency error, the multi-RAT communication device adjusts the frequency of its crystal oscillator to take into account the determined frequency error of the base station, so that the RAT It may be possible to acquire / maintain service with the base station using the corrected frequency.

  Currently, a RAT on a multi-RAT communication device can communicate with many different base stations individually. In conventional networks, the timing mechanisms / clocks of base stations in the same network are usually synchronized to ensure consistent service for devices on that network, so that these base stations in the network Usually has a similar frequency error. However, base stations associated with different networks or service providers typically do not have comparable frequency errors because the separate networks are usually not synchronized with each other. Furthermore, in some rare situations, it is possible that base stations in the same network have different frequency errors for a variety of reasons, such as the aging of frequency generating components on a portion of the base station. There is a case.

  In order to allow a multi-RAT communication device to communicate with and / or receive service from each base station, each of the plurality of RATs has a frequency error of various different base stations / networks. The potential difference in frequency error between different base stations currently presents design and operational challenges for multi-RAT communication devices, as must be considered.

  Various embodiments provide methods, devices, and non-transitory processor-readable storage media for improving the performance of multiple radio access technologies (RATs) on a mobile communication device. The method of an embodiment includes obtaining a recent good system (RGS) value for each of the plurality of RATs, associating the obtained RGS value with each of the plurality of RATs, and the obtained RGS. Storing an association of the value and the obtained RGS value.

  Some implementations may include associating the obtained RGS value with at least one attribute based on the time at which the RGS values of multiple RATs are obtained. In some embodiments, the attributes are: mobile communication device temperature, mobile communication device crystal oscillator temperature, base station identification, subscription identification, mobile communication device geographical location, service network identification, and timestamp Can include one of the following:

  Some implementations include identifying a RAT in a plurality of RATs associated with a request for an RGS value from a requesting entity, retrieving a stored RGS value associated with the identified RAT, and retrieving Sending the requested RGS value to the requesting entity.

  In some embodiments, retrieving a stored RGS value associated with the identified RAT includes identifying a first group of RGS values associated with the identified RAT; and a first of the RGS values. Determining a confidence value for each RGS value in the group; and retrieving a stored RGS value in the first group of RGS values having the largest confidence value in the first group of RGS values. Can be included.

  The method of some embodiments can include adjusting the retrieved RGS value based on a change in at least one stored attribute associated with the retrieved RGS value. Sending to the requesting entity may include sending the adjusted RGS value to the requesting entity.

  In some embodiments, the step of adjusting the retrieved RGS value based on the change in at least one stored attribute associated with the retrieved RGS value includes the step of adjusting the temperature change associated with the retrieved RGS value. Adjusting the retrieved RGS value based on may be included.

  In some embodiments, retrieving a stored RGS value associated with the identified RAT includes identifying a first group of RGS values associated with the identified RAT; and a first of the RGS values. In response to determining whether there is at least one stored RGS value in the group and no RGS value in the first group of RGS values, a substitution not associated with the identified RAT Retrieving a stored RGS value of.

  In some embodiments, in response to determining that there is at least one RGS value in the first group of RGS values, the at least one RGS value in the first group of RGS values is trusted. Determining whether there is a confidence value that satisfies the confidence threshold, and any RGS value in the first group of RGS values associated with the identified RAT is a confidence value that satisfies the confidence threshold Retrieving a substitute stored RGS value that is not associated with the identified RAT, and an RGS value in the first group of RGS values associated with the identified RAT, In response to determining that there is a confidence value that satisfies the confidence threshold, the stored RGS value in the first group of RGS values having the largest confidence value in the first group of RGS values is A step of removing.

  In some embodiments, retrieving a substitute stored RGS value that is not associated with the identified RAT includes identifying a subscription associated with the identified RAT and an RGS associated with the identified subscription. Identifying a second group of values and determining a confidence value for each stored RGS value in the second group of RGS values may be included.

  The method of some embodiments includes determining whether there are stored RGS values in the second group of RGS values that satisfy the confidence threshold, and satisfying the confidence threshold. In response to determining that there is a stored RGS value in the second group of RGS values, storing the RGS value in the second group having the greatest confidence value in the second group of RGS values. Retrieving the determined RGS value.

  The method of some embodiments is responsive to determining that there are no stored RGS values in the second group of RGS values associated with the identified subscription that satisfy the confidence threshold. In response to determining whether there is a stored RGS value available on the mobile communication device and determining that there is a stored RGS value available on the mobile communication device, the maximum confidence value In response to determining that there are no stored RGS values available on the mobile communication device and RGS using a mathematical model in response to determining that there are no stored RGS values available on the mobile communication device Generating a value approximation.

  The method of some embodiments includes determining an updated RGS value of the RAT based on a current network condition of the RAT of the plurality of RATs, associating the updated RGS value with the RAT, and updating Storing the updated RGS value and the association of the updated RGS value with the RAT.

  The method of some embodiments may include associating the updated RGS value with at least one current attribute based on the time at which the updated RGS value is determined, and the updated RGS value and Storing the updated RGS value association with the RAT includes an updated RGS value, an updated RGS value association with the RAT, and an updated RGS value association with at least one current attribute; A step of storing may be included.

  The method of some embodiments includes determining an updated RGS value of the RAT based on a current network condition of the RAT of the plurality of RATs and retrieving a stored RGS value associated with the RAT. And changing the stored RGS value associated with the RAT based on the updated RGS value.

  The method of some embodiments includes identifying at least one attribute associated with the updated RGS value based on the time at which the updated RGS value is determined, and at least associated with the updated RGS value. Modifying at least one attribute associated with the changed RGS value based on the one attribute.

  The method of some embodiments includes retrieving an RGS value associated with the RAT in response to receiving a sleep notification from the RATs in the plurality of RATs, and a time based on the sleep notification and the retrieved RGS value. Determining a time period and configuring the RAT to wake up upon expiration of the time period may be included.

  The method of some embodiments may include adjusting the retrieved RGS value based on a change in at least one stored attribute associated with the retrieved RGS value, the sleep notification and the retrieved Determining the time period based on the RGS value may include determining the time period based on the sleep notification and the adjusted RGS value.

  The method of some embodiments includes determining that a RAT in the plurality of RATs is attempting to perform one of a network acquisition operation and a network reacquisition operation and retrieving an RGS value associated with the RAT. And configuring the RAT to perform one of a network acquisition operation and a network reacquisition operation based on the retrieved RGS value.

  The method of some embodiments can include adjusting the retrieved RGS value based on a change in at least one stored attribute associated with the retrieved RGS value. And configuring the RAT to perform one of the network acquisition operation and the network reacquisition operation based on the adjusted RGS value is based on one of the network acquisition operation and the network reacquisition operation. One can include configuring the RAT to perform one.

  The method of some embodiments includes retrieving an RGS value associated with a base station in response to determining that a RAT in the plurality of RATs is performing a handover operation to the base station; Configuring the RAT to perform a handover operation to the base station based on the RGS value.

  The method of some embodiments can include adjusting the retrieved RGS value based on a change in at least one stored attribute associated with the retrieved RGS value. And configuring the RAT to perform a handover operation to the base station based on the RRS includes configuring the RAT to perform the handover operation to the base station based on the adjusted RGS value. Can do.

  In some embodiments, the method can include in response to determining that the first RAT in the plurality of RATs is performing an inter-RAT measurement of the second RAT in the plurality of RATs to the second RAT. Retrieving an associated RGS value and configuring the first RAT to perform an inter-RAT measurement of the second RAT based on the retrieved RGS value can be included.

  The method of some embodiments can include adjusting the retrieved RGS value based on a change in at least one stored attribute associated with the retrieved RGS value. The step of configuring the first RAT to perform the inter-RAT measurement of the second RAT based on the second RAT is performed to perform the inter-RAT measurement of the second RAT based on the adjusted RGS value. A step of configuring one RAT may be included.

  Various embodiments can include a mobile communication device configured with processor-executable instructions for performing the operations of the methods described above.

  Various embodiments can include a mobile communication device having means for performing the functions of the operations of the methods described above.

  Various embodiments can include a non-transitory processor-readable medium having stored thereon processor-executable instructions configured to cause a processor of a mobile communication device to perform the operations of the methods described above.

  The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate exemplary embodiments of the invention, and together with the general description given above and the detailed description given below, It works to explain the features of the invention.

1 is a communication system block diagram illustrating a mobile telephony network suitable for use with various embodiments. FIG. FIG. 6 is a component block diagram illustrating a mobile communication device according to various embodiments. FIG. 3 is a signaling and call flow diagram illustrating acquisition and updating of conventional RGS values by components of a mobile communication device. FIG. 7 is a signaling and call flow diagram illustrating acquisition and updating of RGS values by components of a mobile communication device according to various embodiments. 6 is a data table showing RGS value associations for use with various embodiments. 6 is a data table showing RGS value associations for use with various embodiments. FIG. 4 is a process flow diagram illustrating a method for associating an RGS value with a RAT, according to various embodiments. FIG. 4 is a process flow diagram illustrating a method for sending RGS values associated with a RAT to a requesting entity, according to various embodiments. FIG. 4 is a process flow diagram illustrating a method for obtaining an RGS value based on a confidence value of an RGS value, according to various embodiments. In response to determining that a RAT is not associated with any RGS value or with an RGS value that satisfies a confidence threshold, according to various embodiments, a method for obtaining a surrogate RGS value for a RAT is provided. FIG. FIG. 6 is a process flow diagram illustrating a method for updating RGS values associated with a RAT, according to various embodiments. FIG. 6 is a process flow diagram illustrating a method for updating RGS values associated with a RAT, according to various embodiments. FIG. 6 is a process flow diagram illustrating a method for configuring a RAT to sleep based on an RGS value associated with the RAT, according to various embodiments. FIG. 4 is a process flow diagram illustrating a method for configuring a RAT to perform network acquisition or network reacquisition based on RGS values associated with the RAT, according to various embodiments. FIG. 5 is a process flow diagram illustrating a method for configuring a RAT to perform a handover operation based on an RGS value associated with a base station that the RAT is about to switch to, according to various embodiments. FIG. 6 is a process flow diagram illustrating a method for configuring a first RAT to perform inter-RAT measurements of a second RAT based on RGS values associated with the second RAT, according to various embodiments. FIG. 6 is a component block diagram illustrating a mobile communication device suitable for performing the methods of some embodiments.

  Various embodiments will be described in detail with reference to the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts. Reference is made to the specific examples, and the embodiments are illustrative and are not intended to limit the scope of the invention or the claims.

  As used herein, the terms “wireless device”, “mobile communication device”, and “multi-RAT communication device” are used interchangeably and are cellular telephones, smartphones, personal or mobile multimedia players. , Personal digital assistant, laptop computer, personal computer, tablet computer, smart book, palmtop computer, wireless e-mail receiver, cellular phone with multimedia internet, wireless game console, and programmable processor, memory, and at least two Refers to any one or all of similar personal electronic devices including circuitry for connecting to a mobile communication network. Various embodiments may be useful within a mobile communication device such as a smartphone, and thus such devices are referenced in the description of the various embodiments. However, the various embodiments can maintain multiple RATs associated with one or more subscriptions / SIMs separately and are useful in all electronic devices that utilize one or more RF resources There is a possibility.

  Conventional mobile communication devices include a crystal oscillator manager (eg, a processor or controller) that obtains the current frequency error value of the base station (eg, from a RAT on the device). This frequency error value is sometimes referred to as the “RGS value”, which represents the “Recent Good System” value, and the crystal oscillator manager is usually by stabilizing the frequency and The RGS value is utilized to enable the RAT to perform network acquisition and / or network reacquisition operations by adjusting the frequency of communications exchanged with base stations of the RAT. The crystal oscillator manager programs the RAT sleep cycle by converting the RGS value from the frequency domain to a time domain value that is used to determine the time period during which the RAT can perform sleep / idle mode operation. Also use the RGS value. For example, to ensure that the RAT sleeps for the expected or desired amount of time, the crystal oscillator manager may determine the appropriate amount of time that the RAT allows to sleep. The RGS value can be used to adjust the current frequency value of the crystal oscillator.

  In conventional multi-RAT communication devices, the crystal oscillator manager maintains only one RGS value (sometimes referred to as a “system RGS value”) to service all RATs operating on the multi-RAT communication device. In current practice, the crystal oscillator manager periodically receives updated RGS values from multiple RATs and keeps only the latest RGS value received from any one of the multiple RATs. For example, the crystal oscillator manager replaces the first system RGS value received from the first RAT with the second system RGS value received from the second RAT, and eventually the second system RGS value is May be replaced with a third system RGS value received from the third RAT at a later time. Due to the potential difference in frequency error between different networks (or even between individual base stations in the same network), the use of a single system RGS value is often an error in the sleep duration calculation. And problems in performing acquisition / re-acquisition for many of the multiple RATs. Further, in many scenarios, slew error during individual pilot timing / slotted mode has been observed in mobile devices that use only one system RGS value to service multiple RATs.

  In overview, various embodiments provide within a mobile communication device for maintaining at least one separate RGS value for each of a plurality of RATs operating on a mobile communication device (e.g., a multi-RAT communication device). Provide a method to be performed. Specifically, a device processor (e.g., a crystal oscillator manager) on a mobile communication device can maintain a separate up-to-date RGS value for each of a plurality of RATs, Can be associated with RGS values. By storing each RGS value of multiple RATs, the device processor can determine the appropriate RGS value for each RAT, such as acquisition / re-acquisition operation, sleep scheduling calculation, and inter-handover / RAT measurement operation. It can be guaranteed to be used to facilitate. As a result, various embodiments can improve the performance of each RAT and the overall performance of the mobile communication device.

  In various embodiments, the mobile communication device can include a crystal oscillator for use with the frequency stabilization and timing calculations described above, and the crystal oscillation frequency characteristics vary based on temperature. there's a possibility that. For example, the oscillation frequency of a crystal can be lower when exposed to relatively low temperatures and higher when exposed to relatively high temperatures. In some embodiments, a device processor operating on the mobile communication device can adjust the RGS value based on the effect of temperature on the operating frequency of the crystal oscillator. In the above example, the device processor can increase the RGS value to compensate for the lower temperature and can decrease the RGS value to compensate for the higher temperature. In some embodiments, the crystal oscillator can be a “temperature compensated” crystal oscillator, which means that the oscillator is designed to minimize the effect of temperature on the crystal's oscillation frequency. To do. In other embodiments, the crystal oscillator may be a “non-temperature compensated” crystal oscillator, and the device processor may implement the method of embodiments to compensate for the relatively greater effect of temperature on the operating frequency of the crystal oscillator. Various operations can be performed.

  In some embodiments, the mobile communication device processor can maintain a record of temperature changes that may affect the performance of the crystal oscillator for each of the plurality of RATs, and the RGS value of that RAT. The unique RGS value of each RAT can be adjusted based on the unique temperature change. Specifically, the mobile communication device processor can associate the temperature of the mobile communication device with the RGS value at the time when the RAT reports the RGS value to the device processor. Thus, at a later time, the mobile communication device processor compares the stored temperature value associated with the RGS value with the current temperature of the mobile communication device and determines the RGS value based on the difference between these temperatures. By adjusting, the RGS value can be adjusted. While useful in a variety of mobile communication devices, such embodiments can be particularly useful in communication devices that include non-temperature compensated crystal oscillators. This is because the relatively larger variation in operating frequency in these crystal oscillators is effectively taken into account by keeping a record of temperature changes that can affect the RGS value associated with a particular RAT. Because it can be done.

  The stored RGS value may reflect a particular combination of factors and conditions experienced / observed on the mobile communication device at the first time that the RGS value was received on the mobile communication device. Examples of factors and conditions that may be experienced / observed on a mobile communication device are the device / crystal oscillator temperature (described above) relative to the RGS value when the RGS value was received / obtained , Geographic location, time (eg, timestamp), subscription, etc. Thus, the stored RGS value may be most useful in situations where the current condition of the mobile communication device is similar to the condition that existed when the RGS value was first received / obtained.

  In some embodiments, the mobile communication device processor records a condition / situation surrounding the RGS value by storing and maintaining at least one “attribute” for each RGS value stored on the mobile communication device. Can be maintained. In such an embodiment, the attributes of the RGS value may describe one aspect of the condition / situation when the RGS value was first obtained / received on the mobile communication device. Specifically, attributes associated with RGS values include one or more RATs associated with RGS values, subscriptions associated with one or more RATs, mobile communication device temperatures, crystal oscillator temperatures, service networks One or more of the times when the RGS value was obtained, such as GSM (R), WCDMA (R), the geographical location / GPS coordinates of the mobile communication device, and the time stamp shape Can be included. In such embodiments, the mobile communication device processor may use these attributes to distinguish RGS values to select / use the stored RGS values that are most appropriate for the current condition / situation of the mobile communication device. Can be used. For example, the mobile communication device processor can determine the current geographic location of the mobile device and can retrieve a stored RGS value associated with the current geographic location.

  In some embodiments, the mobile communication device processor may store and maintain each RGS value and the association / attribute of that RGS value in memory. RGS values may be stored and maintained in lookup tables, databases, associated lists, and / or any other known data structure or storage mechanism.

  In some embodiments, the mobile communications device processor identifies a requesting entity (e.g., by sending an RGS value associated with the request to the requesting entity by identifying the RAT associated with the request. Can respond to RGS value requests from RAT, sleep controller, GPS module / receiver, etc. For example, the first RAT may request an RGS value to allow re-acquisition activity to be performed after the first RAT exits sleep mode, and the mobile communication device processor may The RAT can be identified as being associated with the request, and the RGS value associated with the first RAT can be returned to the first RAT.

  As explained, RGS values are best used in situations where the current condition / situation of the mobile communication device is similar to the condition / situation that occurred when the RGS value was received / obtained on the mobile communication device. May be suitable. In other words, the RGS value can be very useful (ie, reliable) when the attribute associated with the RGS value matches the current conditions of the mobile communication device. In view of this, in some embodiments, a mobile communication device processor may request an entity based on a “trust value” of an RGS value that may be a measure of the predicted reliability or accuracy of the RGS value. The RGS value stored for can be retrieved. For example, a RAT that uses an RGS value with a high confidence value may have a lower confidence value because the higher confidence value may be more accurate or reliable, thereby reducing the overall search window required for service acquisition. Service can be acquired faster than when using the RGS value.

  In some embodiments, the RGS value confidence value may be based on a comparison between the attribute associated with the stored RGS value and the current condition / situation of the mobile communication device. For example, a low confidence value for a stored RGS value relates to a condition / attribute in which the stored RGS value is significantly different from the condition currently experienced / observed on the mobile communication device (i.e., that condition / Can be shown to be suitable for use in attributes). In another example, a stored RGS value can have a high confidence value when its attributes are similar to the current situation.

  Accordingly, in some embodiments, in response to receiving a request for the RGS value of the first RAT from the requesting entity, the mobile communication device processor has a confidence value that the stored RGS value has a sufficiently high reliability value. As such, it may initially attempt to retrieve the stored RGS value associated with the first RAT. In such an embodiment, the mobile communications device processor determines whether there is a stored RGS value associated with the first RAT that satisfies a minimum reliability threshold (e.g., is greater than or equal to). The stored RGS value having the reliability satisfying the reliability threshold value can be retrieved. In response to determining that any stored RGS value associated with the RAT does not satisfy the reliability threshold, the mobile communications device processor determines the reliability from the group of RGS values associated with the first RAT subscription. Can attempt to retrieve a stored RGS value that satisfies the threshold (e.g., related to the second RAT associated with the same subscription), and after that fails, satisfies the confidence threshold You can try to retrieve all other stored RGS values. If there are no stored RGS values available, the mobile communication device processor can generate an RGS value approximation using a mathematical model (see FIG. 7C).

  In some embodiments, the mobile communication device processor can monitor changes in RAT network conditions related to frequency error. In response to detecting a change in frequency error (e.g., after reselection of the RAT to another base station), the mobile communications device processor determines an updated RGS value for the RAT based on the RAT's current network conditions. And an updated RGS value can be associated with the RAT. In some embodiments, the mobile communication device processor may also associate at least one attribute of the current condition / situation of the mobile communication device with the updated RGS value. For example, the current temperature of the crystal oscillator can be associated with the updated RGS value to ensure that future temperature correction / compensation of the updated RGS value is accurate.

  In some embodiments, the mobile communication device processor can change a previously stored RGS value based on the updated RGS value. In other words, rather than overwriting a previously stored RGS value with a potentially fake updated RGS value, the mobile communication device processor may adversely affect performance on the mobile communication device. In order to prevent dramatic changes in RGS, previously stored RGS values can be adjusted (eg, by averaging two RGS values).

  In some embodiments, a mobile communication device processor (e.g., a sleep controller) on a mobile communication device is allowed to remain in sleep / idle mode based on an RGS value associated with the RAT. The period can be determined. As a result, the mobile communication device processor can ensure that the calculated sleep duration of the RAT is accurate (ie, not too long and not too short). In some embodiments, the mobile communication device processor adjusts the RGS value based on a temperature change associated with the RGS value to avoid timing errors caused by changes in the operating frequency of the crystal oscillator of the mobile communication device. RGS value can be adjusted / compensated based on a change in at least one stored attribute associated with the RGS value.

  In some embodiments, the mobile communication device processor on the mobile communication device can obtain an RGS value associated with the RAT, and the RAT uses the RGS value to perform a network acquisition operation or a network reacquisition operation. The RGS value can be supplied to the RAT in order to be able to do so. In some embodiments, the mobile communication device processor can adjust / compensate the RGS value based on a change in at least one stored attribute associated with the RGS value. For example, the mobile communication device processor may use the RGS value based on the temperature change associated with the RGS value to provide the RAT with the correct frequency to allow the RAT to establish or re-establish service with the base station. Can be adjusted.

  In some embodiments, in response to determining that the RAT is or will perform a handoff operation to the base station, the mobile communication device processor on the mobile communication device is associated with the base station. The RGS value can be obtained and the RGS value can be provided to the RAT to allow the RAT to perform a handoff operation using the RGS value.

  In some embodiments, in response to determining that the first RAT is or is about to perform an inter-RAT measurement of the second RAT, the mobile communication device processor measures the second measured RAT. The RGS value associated with the RAT can be obtained and the RGS value can be given to the RAT to allow the first RAT to perform inter-RAT measurements using that RGS value. .

  Various embodiments may be implemented in various communication systems 100, such as at least two mobile telephony networks, an example of which is shown in FIG. First mobile network 102 and second mobile network 104 typically include a plurality of cellular base stations (eg, first base station 130 and second base station 140), respectively. The first mobile communication device 110 may be in communication with the first mobile network 102 via a cellular connection 132 to the first base station 130. The first mobile communication device 110 may be in communication with the second mobile network 104 via a cellular connection 142 to the second base station 140. The first base station 130 can be in communication with the first mobile network 102 via a wired connection 134. The second base station 140 can be in communication with the second mobile network 104 via a wired connection 144.

  The second mobile communication device 120 may similarly be in communication with the first mobile network 102 via a cellular connection 132 to the first base station 130. The second mobile communication device 120 may be in communication with the second mobile network 104 via a cellular connection 142 to the second base station 140. Cellular connections 132 and 142 may be made over two-way wireless communication links, such as 4G, 3G, CDMA, TDMA, WCDMA®, GSM®, and other mobile telephony communication technologies.

  Although the mobile communication devices 110 and 120 are shown connected to two mobile networks 102 and 104, in some embodiments (not shown), the mobile communication devices 110 and 120 have more than one mobile It can include more than one subscription to the network and can connect to these subscriptions in a manner similar to that described above.

  In some embodiments, the first mobile communication device 110 can establish a wireless connection 152 with a peripheral device 150 used in connection with the first mobile communication device 110. For example, the first mobile communication device 110 can communicate with a Bluetooth enabled personal computing device (eg, a “smart watch”) via a Bluetooth link. In some embodiments, the first mobile communication device 110 can establish a wireless connection 162 with the wireless access point 160, such as via a Wi-Fi connection. The wireless access point 160 may be configured to connect to the Internet 164 or another network via a wired connection 166.

  Although not shown, the second mobile communication device 120 may similarly be configured to connect to the peripheral device 150 and / or the wireless access point 160 via a wireless link.

  In some embodiments, each of the mobile communication devices 110, 120 can communicate with the first base station 130 and the second base station 140 using different RATs. For example, the first mobile communication device 110 has a first RAT (e.g., CDMA RAT) for communicating with the first mobile network 102 (e.g., CDMA network) via the first base station 130. And has a second RAT (eg, GSM® RAT) for communicating with the second mobile network 104 (eg, GSM® mobile network) via the second base station 140 be able to. In some embodiments, the RAT on the mobile communication device 110, 120 is replaced with the same subscription (e.g., within an SRLTE communication device) or with a different subscription (e.g., within a DSDS communication device or DSDA). Can operate (within a communication device).

  FIG. 2 is a functional block diagram of a mobile communication device 200 suitable for implementing various embodiments. According to various embodiments, the mobile communication device 200 may be similar to one or more of the mobile communication devices 110, 120 described with reference to FIG. 1-2, the mobile communication device 200 can include a first SIM interface 202a, the first SIM interface 202a being a first identification module SIM- associated with a first subscription. 1 Can receive 204a. The mobile communication device 200 can optionally include a second SIM interface 202b, the second SIM interface 202b can receive a second identification module SIM-2 204b associated with the second subscription. it can.

  The SIM in various embodiments can be a Universal Integrated Circuit Card (UICC) that is configured with a SIM application and / or USIM application to allow access to GSM and / or UMTS networks. . The UICC can also provide storage for phone books and other applications. Alternatively, in a CDMA network, the SIM may be a UICC removable user identity module (R-UIM) or a CDMA subscriber identity module (CSIM) on the card. The SIM card can have a CPU, ROM, RAM, EEPROM, and input / output circuits. An integrated circuit card identity (ICCID) SIM serial number may be printed on the SIM card for identification. However, the SIM may be implemented in a portion of the memory of the mobile communication device and thus need not be a separate or removable circuit, chip, or card.

  The SIM used in various embodiments includes user account information, international mobile subscriber identity (IMSI), a set of SIM application toolkit (SAT) commands, and other network provisioning information, while at the same time the user's contact phone. A storage space for the book database can be provided. As part of the network provisioning information, the SIM provides a home identifier (e.g., System Identification Number (SID) / Network Identification Number (NID) pair, Home PLMN (HPLMN) code, etc.) to indicate the SIM card network operator provider. Can be remembered. Integrated Circuit Card Identification (ICCID) A SIM serial number is printed on the SIM card for identification.

  The mobile communication device 200 can include at least one controller, such as a general purpose processor 206, that can be coupled to a coder / decoder (codec) 208. Codec 208 may be coupled to speaker 210 and microphone 212. General purpose processor 206 may also be coupled to at least one memory 214. Memory 214 may be a non-transitory computer readable storage medium that stores processor-executable instructions. For example, the instructions can include routing communication data for the first or second subscription via a corresponding baseband RF resource chain.

  The memory 214 may store an operating system (OS) and user application software and executable instructions. The memory 214 can also store application data such as an array data structure. In some embodiments, the memory 214 may include RGS values associated with each of a plurality of RATs operating on the mobile communication device 200, as well as subscription, base station, network / service provider, geographic location, temperature, time. One or more lookup tables, including / etc / time stamps and / or other information related to the RGS value of each RAT (e.g., described with reference to FIGS. 5A-5B) Can also be stored. For example, a lookup table stored in memory 214 may be used to determine a particular RGS value to be used for a currently operating RAT on behalf of a particular subscription and / or communicate with a particular base station Can contain useful information.

  General purpose processor 206 and memory 214 may each be coupled to at least one baseband modem processor 216. Each SIM and / or RAT (eg, SIM-1 204a and SIM-2 204b) in mobile communication device 200 may be associated with a baseband RF resource chain. The baseband RF resource chain can include a baseband modem processor 216, which can perform baseband / modem functions for communicating with / controlling the RAT, One or more amplifiers and radios generally referred to in the document as RF resources (eg, RF resource 218a and optionally RF resource 218b) may be included. In some embodiments, the baseband RF resource chain can share the baseband modem processor 216 (ie, a single device that performs all RAT baseband / modem functions on the wireless device). In other embodiments, each baseband RF resource chain can include physically or logically separate baseband processors (eg, BB1, BB2).

  Each of the RF resources 218a, 218b may be a transceiver associated with one or more RATs and may perform the transmit / receive functions of the wireless device on behalf of their respective RATs. For example, a first RAT (eg, GSM® RAT) may be associated with RF resource 218a and a second RAT (eg, CDMA RAT or WCDMA® RAT) is associated with RF resource 218b. Can be. In another example, both the first RAT and the second RAT may be associated with the RF resource 218a. The RF resources 218a, 218b can include separate transmitter and receiver circuits, or can include a transceiver that combines transmitter and receiver functions. The RF resources 218a, 218b may each be coupled to a wireless antenna (eg, a first wireless antenna 220a or an optional second wireless antenna 220b). The RF resources 218a, 218b may also be coupled to the baseband modem processor 216.

  In some embodiments, general purpose processor 206, memory 214, baseband processor 216, and RF resources 218a, 218b may be included in mobile communication device 200 as a system on chip. In some embodiments, the first SIM 204a and the second SIM 204b and their corresponding interfaces 202a and 202b can be external to the system on chip. In addition, various input and output devices, such as interfaces or controllers, can be coupled to components on the system on chip. Examples of user input components suitable for use within the mobile communication device 200 can include, but are not limited to, a keypad 224, a touch screen display 226, and a microphone 212.

  In some embodiments, keypad 224, touch screen display 226, microphone 212, or a combination thereof may perform the function of receiving a request to initiate an outgoing call. For example, the touch screen display 226 may receive a contact selection from a contact list or receive a phone number. In another example, one or both of touch screen display 226 and microphone 212 may perform the function of receiving a request to initiate an outgoing call. For example, the touch screen display 226 may receive a contact selection from a contact list or receive a phone number. As another example, the request to initiate an outgoing call can be in the form of a voice command received via microphone 212. An interface may be provided between the various software modules and functions within the mobile communication device 200 to allow communication between them as is known in the art.

  The two SIMs 204a, 204b, baseband processors BB1, BB2, RF resources 218a, 218b, and wireless antennas 220a, 220b can work together to form two or more RATs. For example, SIM, baseband processor, and RF resources can be configured to support two different RATs. More RATs can be supported on the mobile communication device 200 by adding more SIM cards, SIM interfaces, RF resources, and / or antennas for connection to additional mobile networks.

  The mobile communication device 200 manages RGS values associated with each of a plurality of RATs on the mobile communication device 200, such as by storing the RGS values in a lookup table in the memory 214 as described above. The crystal oscillator manager 230 may be configured. Crystal oscillator manager 230 may be implemented as a software module implemented on general-purpose processor 206 or baseband modem processor 216, as a separate hardware component, or as a combination of hardware and software. The crystal oscillator manager 230 is described in various manners such as sleep operation, acquisition operation, reacquisition operation, handover operation, and / or inter-RAT measurement where each of the plurality of RATs is described (eg, see FIGS. 4-12). Can interact with other components on the mobile communication device 200, such as the sleep controller 232, in order to be able to perform various operations. For example, crystal oscillator manager 230 can receive a temperature measurement of mobile communication device 200 (and / or a crystal oscillator (not shown) temperature measurement) from temperature sensor 236, and crystal oscillator manager 230 can receive one Or these temperature measurements can be used to adjust multiple RGS values.

  In some embodiments, the sleep controller 232 may be configured to determine a time period during which the RAT can perform sleep and / or idle mode operation in response to receiving a sleep notification from the RAT. Specifically, the sleep controller 232 can obtain the RGS value related to the notified RAT, and can calculate the sleep program / sleep duration of the RAT based on the retrieved RGS value.

  In some embodiments, the sleep controller 232 can convert the RGS value to the time domain and / or on the mobile communication device 200 that may have occurred since the RGS value was first stored. The RGS value can be adjusted in response to temperature changes. Sleep controller 232 is implemented as a software module implemented on general-purpose processor 206, baseband modem processor 216, or crystal oscillator manager 230, as a separate hardware component, or as a combination of hardware and software. obtain.

  In some embodiments, the mobile communication device 200 can include a global positioning system (GPS) module 234 (eg, a GPS receiver) configured to provide location information to the general purpose processor 206. As described, location information such as that provided by the GPS module 234 may be used to select an RGS value stored in memory and / or when the stored RGS value is unreliable. Alternatively, it may be used by general purpose processor 206. In such an embodiment, the GPS module 234 may obtain a global positioning system RGS value associated with the GPS module 234.

FIG. 3 shows that various components on a conventional mobile communication device rely on only one system RGS value to allow multiple RATs to perform sleep, acquire, and / or reacquire operations. FIG. 3 is a signaling and call flow diagram 300 illustrating example communications between various components. Referring to FIGS. 1-3, a conventional communication device has a first RAT 302 (labeled as `` RAT <sub>1</sub> '' in FIG. 3), a second RAT 308 (labeled as `` RAT ₂ '' in FIG. 3) , A sleep controller 304 (eg, sleep controller 232 of FIG. 2), and a crystal oscillator manager 306 (eg, crystal oscillator manager 230 of FIG. 2).

In the example shown in FIG. 3, the first RAT 302 must use the RGS value to determine the actual frequency of that base station in order to obtain service from a nearby base station, so the network acquisition RGS value must be acquired in order to execute Thus, after power-up (not shown), the first RAT 302 sends a request to the crystal oscillator manager 306 via the signaling 310 and receives an RGS value (ie, an RGS ₀ value) from the crystal oscillator manager 306.

  In conventional mobile communication devices, the crystal oscillator manager 306 provides a unique RGS value (i.e., system RGS value), such as the last or latest RGS value received from any of multiple RAT operations on the mobile communication device. Remember. Thus, in response to receiving a request for an RGS value from the first RAT 302, the crystal oscillator manager sends a system RGS value to the first RAT 302.

In acquiring the RGS ₀ value from the crystal oscillator manager 306, the first RAT 302 performs an acquisition operation 312 for the RGS ₀ value. In the example shown in FIG. 300, the RGS ₀ value may be associated with the first RAT 302, thereby allowing the first RAT 302 to perform the acquisition operation 312 successfully.

The first RAT 302 determines an updated RGS value in the course of its communication with its base station (not shown) and / or an RGS value updated from the base station (i.e., RGS ₁ value). Receive. The first RAT 302 reports the RGS ₁ value to the crystal oscillator manager 306 via signaling 314, and in response, the crystal oscillator manager 306 overwrites the RGS ₀ value with the RGS ₁ value in operation 315.

At some later time, crystal oscillator manager 306 receives another updated RGS value (ie, RGS ₂ value) from second RAT 308 via signaling 316. The RGS ₂ value may be specific to the base station of the second RAT 308 (i.e. the particular frequency error of that base station) and is therefore only suitable for use with the second RAT 308. Thus, it may be unsuitable for use with all other RATs (eg, the first RAT 302) on conventional mobile communication devices. However, according to conventional implementations, the crystal oscillator manager 306 retains only the latest RGS value, and therefore received from the first RAT 302 by the RGS ₂ value received from the second RAT 308 in operation 317. Overwrite the specified RGS ₁ value.

  From time to time, multiple RATs on a mobile communication device may need to enter sleep / idle mode, for example, to conserve power when these RATs are not performing receive or transmit operations. In anticipation of entering sleep / idle mode, the RAT can notify the sleep controller.

For example, in the example shown in diagram 300, the first RAT 302 sends a sleep notification to the sleep controller 304 via signaling 318 shortly before entering sleep or idle mode in operation 324. In response to receiving the sleep notification, the sleep controller 304 sends a request for the RGS value to the crystal oscillator manager 306 via the signaling 320, and the system RGS value stored from the crystal oscillator manager 306 (i.e., the RGS ₂ value). Receive.

In operation 322, the sleep controller 304 uses the RGS ₂ value to determine the period of time (i.e., sleep duration) that must remain dormant / idle before the first RAT 302 is reactivated. judge. The sleep controller 304 must keep frequency information in the RGS _binary value how long the first RAT 302 must sleep before the first RAT 302 has to regain service from that base station. This behavior can be achieved by converting to time domain / timing information that can be used to determine whether. Thus, after the first RAT 302 enters sleep mode at operation 324, the sleep controller 304 sends a wake-up signal 326 to the first RAT 302 at the end of the sleep duration calculated at operation 322.

The sleep duration calculated in operation 322 is based on the RGS ₂ value received from the second RAT 308 and is not based on the RGS value associated with the first RAT 302 (e.g., the RGS ₁ value), so this sleep duration The time may be incorrect for the second RAT. In other words, the sleep duration accurately indicates the timing and / or frequency information of the first RAT302 network and / or base station because the RGS ₂ value indicates the frequency error information of the second RAT308 base station / network. May not reflect. As a result, the sleep controller 304 sends a wakeup signal 326 to the first RAT 302 at a time other than the desired or expected wakeup time of the first RAT 302, potentially causing the pilot timing error to the first RAT 302. Or you may experience a through error.

Further, in order to perform the reacquisition operation, the first RAT 302 requests the RGS ₂ value from the crystal oscillator manager 306 via the signaling 328 and receives the RGS ₂ value from the crystal oscillator manager 306. As described, the RGS ₂ value reflects the frequency error of the base station of the second RAT 308 and does not reflect the frequency error of the base station associated with the first RAT 302, so the RGS ₂ value is May only be useful for operations related to RAT308. Thus, when the first RAT 302 attempts to perform the reacquisition operation 330 using the RGS ₂ value, the first RAT 302 may fail to reacquire service (i.e., block 332). is there.

  As seen in the example shown in FIG. 300, a conventional system stores a unique system RGS value to support sleep, acquisition, and reacquisition operations of multiple RATs operating on a mobile communication device. The method uses sleep timing and acquisition / re-acquisition when a system RGS value is received from one RAT (eg, second RAT 308) and used by or instead of another RAT (eg, first RAT 302). It can cause substantial problems with operation. As a result, the overall performance of the mobile communication device can suffer.

  Various embodiments are conventional, such as those described with reference to FIG. 3, by configuring the crystal oscillator manager to store a separate RGS value for each of a plurality of RATs on a mobile communication device. Address mobile communication device limitations.

  FIG. 4 is a signaling and call flow diagram 400 illustrating communication between various components on a mobile communication device (eg, mobile communication device 200 of FIG. 2) according to various embodiments. With reference to FIGS. 1-4, the mobile communication device can include a first RAT 302, a sleep controller 304, a crystal oscillator manager 306, and a second RAT 308.

In the illustrated example, the crystal oscillator manager 306 may have previously stored the RGS value associated with the first RAT 302 (i.e., the RGS ₀ value), which means that the first RAT 302 It means that the RGS ₀ value may have been previously reported to the crystal oscillator manager 306 as an indication of the RAT 302 base station / network frequency error.

  After power-up or reactivation (not shown), the first RAT 302 determines the actual frequency required to communicate with a nearby base station associated with or recently used by the first RAT 302 In order to do so, it may be necessary to obtain the latest RGS value from the crystal oscillator manager 306. Thus, the first RAT 302 can send a request for the latest RGS value to the crystal oscillator manager 306 via signaling 402. In some embodiments, this request may include information that may allow the crystal oscillator manager 306 to identify the required RAT.

In response to receiving the request from the first RAT 302, the crystal oscillator manager 306 can identify the first RAT 302 as being associated with the request, and is associated with the first RAT via signaling 402. An RGS value (ie, an RGS ₀ value) can be returned. In some embodiments, the crystal oscillator manager 306 performs a lookup operation in the data table based on at least the first RAT 302 to find an RGS value associated with the first RAT 302 (e.g., As described with reference to FIGS. 5A-5B, the RGS ₀ value can be obtained from a data table stored in memory (eg, memory 214).

In response to receiving the RGS ₀ value, the first RAT 302 may perform an acquisition operation 312 using the RGS ₀ value, as described. Since the RGS ₀ value is associated with the first RAT 302 and the first RAT 302 can use the RGS ₀ value to determine the frequency required to communicate with a nearby base station, the first RAT 302 The RAT 302 can execute the acquisition operation 312 successfully.

At some later time, the first RAT 302 (or another component on the mobile communication device) receives an RGS ₁ value directly from the base station / network of the first RAT 302, or the current RAT 302 current An updated RGS value (ie, an RGS ₁ value) can be obtained by either determining the frequency error of the base station. For example, the first RAT 302 can compare the frequency of communications received from the base station with the expected frequency of the base station and can determine the RGS ₁ value based on the difference. In some embodiments, the RGS ₁ value may reflect the current operating frequency of the crystal oscillator based on the current temperature of the mobile communication device.

The first RAT 302 may send updated RGS values (ie, RGS ₁ values) as well as information identifying the first RAT 302 to the crystal oscillator manager 306 via signaling 403. In response, crystal oscillator manager 306 updates the RGS ₁ value in operation 404, for example, by updating the current RGS value associated with the first RAT 302 in the lookup table (i.e., the RGS ₀ value). Can be associated with the first RAT 302.

In some embodiments, the first RAT 302 further describes the updated RGS value or the context in which the updated RGS value was obtained (i.e., one or more “attributes” for the updated RGS value). Additional information to be sent can be sent to the crystal oscillator manager 306 via signaling 403. In such embodiments, the crystal oscillator manager 306 can associate this additional information with the updated RGS value (eg, as described with reference to FIG. 5B). For example, the first RAT302, because first RAT302 when the first RAT302 won the RGS ₁ value was communicating with the base station with a specific ID in place of the second subscription, RGS ₁ value Can send information indicating that it is related to the second subscription and / or its particular base station.

As described with reference to the first RAT302, second RAT308 also updated RGS value (i.e., RGS ₂ value) can obtain, via the signaling 405, crystal oscillator RGS ₂ value Report to manager 306. In response, the crystal oscillator manager 306 in operation 406, such as by updating the RGS value associated with the second RAT 308 in the lookup table, as described with reference to operation 404, RGS ₂ A value can be associated with the second RAT 308.

In the illustrated example, the first RAT 302 can send a sleep notification 318 to the sleep controller 304 (as described with reference to FIG. 3) before initiating a sleep / idle mode operation in operation 324. In response to receiving the sleep notification 318, the sleep controller 304 can obtain the RGS value associated with the first RAT 302 from the crystal oscillator manager 306 via signaling 407. For example, the sleep controller 304 can send a request for the current RGS value (ie, RGS ₁ value) associated with the first RAT 302 to the crystal oscillator manager 306. In this example, the crystal oscillator manager 306 can obtain the RGS ₁ value of the first RAT 302 by performing a lookup operation based on the identity of the first RAT 302 in the RGS value data table, The oscillator manager 306 can return its RGS ₁ value to the sleep controller 304 via signaling 407.

In operation 408, the sleep controller 304 can determine the sleep duration of the first RAT 302 based on the RGS ₁ value received from the crystal oscillator manager 306 via the signaling 407. The sleep controller 304 can convert the current RGS ₁ value associated with the first RAT 302 from the frequency domain to the time domain value and remain in sleep / idle mode before the first RAT 302 is reactivated. This time domain value can be used to determine the time period that must be achieved. Furthermore, since the current RGS ₁ value is related to the first RAT 302, the sleep controller 304 can accurately determine the sleep duration of the first RAT 302, and the timing when the first RAT 302 wakes up Error and through error can be avoided. Upon expiration of the sleep duration, the sleep controller 304 can send a wake-up signal 412 to the first RAT 302 to cause the first RAT 302 to resume normal operation.

Upon resuming normal operation, the first RAT 302 can send identifying information and a request for RGS value to the crystal oscillator manager 306 via signaling 414 in anticipation of performing a reacquisition operation. As described above, the crystal oscillator manager 306 can retrieve the RGS value associated with the first RAT 302 (i.e., the RGS ₁ value) and pass that RGS ₁ value to the first RAT 302 via the signaling 414. Since this RGS ₁ value can be sent and is related to the first RAT 302 rather than another RAT, the first RAT 302 uses this RGS ₁ value to successfully perform the reacquisition operation 416 be able to.

  5A-5B show that RGS values used for RAT sleep operation, acquisition operation, reacquisition operation, handoff operation, and / or inter-RAT measurement operation are actually associated with or associated with that RAT. Data tables 500, 510 showing various associations of RGS values that can be used to ensure that they are otherwise useful to perform successfully. In some embodiments, the data tables 500, 510 are stored on a device processor (e.g., general purpose processor 206, baseband modem processor 216, crystal oscillator manager 230, FIG. 2) on a mobile communication device (e.g., mobile communication device 200). May be referenced by sleep controller 232, or another controller / processor.

Referring to FIGS. 1, 2, and 4-5B, the data table 500 shows that the device processor has a direct association between each RAT on the mobile communication device and its latest one or more RGS values. It can be a relatively simple lookup table that can be used to maintain. For example, the device processor can receive an RGS value (ie, an RGS ₁ value) from a first RAT, and can store that RGS value and its association with the first RAT in the data table 500. Similarly, the device processor can receive another RGS value (i.e., RGS ₂ value) from the second RAT, store the RGS value in the data table 500, and the RGS value and the second RAT. Associations can be stored. Thus, rather than maintaining only one system RGS value used by each RAT on a mobile communication device, as currently practiced in conventional devices, in various embodiments, the device processor is per RAT. At least one RGS value can be maintained. As a result, the device processor ensures that various components on the mobile communication device (eg, RAT, GPS unit / module, and / or sleep controller) can use the most relevant RGS value when performing various operations. can do. For example, the device processor can send an RGS ₁ value to the first RAT to allow the first RAT to perform a reacquisition operation (eg, described with reference to FIG. 4). .

  In some embodiments, the device processor may store and maintain additional information regarding RGS values, as shown in data table 510. As explained, context associations for RGS values are sometimes sometimes referred to as “attributes” of RGS values.

  In such embodiments, the device processor can store RGS values and associate them with a particular RAT, as described with reference to the data table 500. In addition, the device processor may use various other types of information / attributes that may be useful in allowing the device processor to select the most appropriate RGS value given the current state of the mobile communication device. Can be associated with an RGS value. For example, the RAT identity associated with an RGS value can at least partially describe the circumstances under which the RGS value was obtained. In such an example, the device processor may use the RAT RGS value based on the RAT association with the RGS value.

Within the data table 510, the device processor has the first RGS in the first subscription associated with the first RAT when the first RAT as well as the first RGS value was acquired (i.e., subscription ₁ ). A value (ie, an RGS ₁ value) can be associated. The device processor may have a base station (ie, base station ID 123) and / or service network (ie, service network ID GSM) that was associated with the first RAT when the first RGS value was obtained. Can also be associated with a first RGS value. In some embodiments, the device processor may also associate the temperature of the mobile communication device (and / or the temperature of the crystal oscillator) (i.e., temperature X °) when the RGS value is obtained with the first RGS value. it can.

  In some embodiments, the device processor may determine the time / timestamp when the RGS value is received / reported from the RAT and associate that time with the RGS value. For example, the data table 510 may also include a first RGS value entity corresponding to the time (eg, timestamp A) at which the RGS value was received. In such embodiments, at a later time, the device processor can utilize the time associated with the RGS value in selecting the RGS value to use. For example, since the RGS value can indicate a snapshot of the situation at a particular time, the device processor may have the best chance of reflecting the current conditions of the mobile communication device, and the most recently received You can try to retrieve a fresh or “freshest” RGS value.

  Similarly, in some embodiments, the device processor can associate the RGS value with the GPS coordinates of the mobile communication device at the time the RGS value is received / reported by the RAT. For example, the device processor may store the geographical location of the mobile communication device at the time the RGS value is received / stored (eg, the location of the first RGS value / GPS coordinate Q °). In such embodiments, the device processor may maintain a record of RGS values for a particular geographic area that maintains particular network conditions or has a particular frequency error. Thus, if the requesting entity requests an RGS value (see, e.g., FIG. 7A), the device processor determines the current GPS coordinate of the mobile communication device and associates it closest to the current GPS coordinate of the mobile communication device RGS values with GPS coordinates can be retrieved. This embodiment may allow the mobile communication device to receive service quickly by leveraging the RGS value associated with the mobile network at the current location.

  Thus, by associating an RGS value with one or more attributes that can include RAT, subscription, base station, device temperature and / or crystal oscillator temperature, time / timestamp, geographic location, etc., the device processor May be able to identify the RGS value that may be most appropriate for a given situation based on the context information observed when the RGS value was acquired (i.e., the stored attribute of the RGS value). is there. For example, a RAT may communicate with two different service providers / networks instead of two different subscriptions, and each network may have a different frequency error / RGS value. Thus, in such an example, the device processor maintains separate entries in the data table for the RGS value associated with the RAT and the first subscription and another RGS value associated with the RAT and the second subscription. be able to. As a result, the device processor can return one of these RGS values to the RAT based on the subscription with which the RAT is currently communicating.

  In some embodiments, the device processor may adjust the RGS values stored in the data table 510 to adjust the RGS values to compensate for small changes in mobile communication devices, mobile networks, and other current conditions. Various attributes can be referenced. For example, the device processor can use the temperature associated with the RGS value (i.e., The temperature of the mobile communication device at the time the value is stored can be used. In another example, the performance of the crystal oscillator can change with age, so the device processor determines the range within which the RGS value must be adjusted to take into account the current age of the crystal oscillator However, the time at which the RGS value was acquired / received can be used.

  In some embodiments (see FIGS. 7B-7C), the device processor may determine whether the RGS value is appropriate / reliable for use in acquiring service to determine the likelihood of being reliable. One or more can be compared to the current condition. In such an embodiment, the device processor may determine or calculate an overall “confidence” value for each RGS value used on the mobile communication device. Specifically, the confidence value can indicate the likelihood that the RGS value is accurate with respect to the current conditions / network of the mobile communication device. In other words, the device processor may determine a confidence value associated with each RGS value by determining the difference between the stored characteristic associated with the RGS value and the current condition / characteristic of the mobile communication device. it can.

  For example, as described, the device processor may have different times when the current time, device temperature / crystal oscillator temperature, GPS coordinates, base station ID, subscription ID, and RGS values are received / reported Information related to the RGS value can be stored. Based on this stored information related to the RGS value, the device processor will compare the stored information with the time the mobile communication device is currently experiencing, device temperature / crystal oscillator temperature, GPS coordinates, etc. Can do. Based on this comparison, the mobile communication device is responsive to determining that there is a slight or no difference between the stored attribute associated with the RGS value and the current condition / characteristic of the mobile communication device. It can be determined that the RGS value has high reliability. In contrast, the device processor can determine that the RGS value has low confidence if there is a large difference between the stored attribute associated with the RGS value and the current characteristics of the mobile communication device. . For example, when the temperature of the crystal oscillator when the RGS value is received is higher or lower than the current temperature of the crystal oscillator, the device processor may give a limited value of usefulness in obtaining service Due to some potential frequency error difference, a low confidence value can be assigned to the RGS value. In some embodiments, the device processor can utilize the RGS value confidence value to determine / adjust the length of time to obtain service (ie, the search window). For example, the device processor may increase the duration of the search window for obtaining a service when the RGS value has a low confidence level, and the search window for obtaining the service when the RGS value has a high confidence level. The duration can be reduced.

  In some embodiments (eg, see FIGS. 7B-7C), the device processor can utilize the confidence value of the RGS value for various other purposes. For example, the device processor selects an RGS value to send to the requesting entity based on the RGS value with the highest confidence value to ensure that the requesting entity (eg, RAT) can quickly obtain service. be able to.

  FIG. 6 illustrates a method 600 for associating RGS values to each of a plurality of RATs on a mobile communication device and storing these RGS values for later use with each of the plurality of RATs, according to some embodiments. Show. Method 600 may be performed by a processor (e.g., general purpose processor 206, baseband modem processor 216, crystal oscillator manager 230, crystal oscillator manager 230, another controller, and / or the like of FIG. 2) of a mobile communication device (e.g., mobile communication device 200 of FIG. 2). ).

  Referring to FIGS. 1, 2, and 4-6, after powering on at block 602, the device processor may obtain an RGS value for each of multiple RATs on the mobile communication device at block 604. it can. In some embodiments, the device processor may obtain new or updated RGS values for their respective base stations / networks, e.g., as described (e.g., see FIG. 4). As a result of sending these acquired RGS values to the device processor, RGS values can be received over time from each of the plurality of RATs.

  In block 606, the device processor may associate the obtained RGS value with each of the plurality of RATs, such as by determining the identity of the RAT reporting the RGS value. In some embodiments of the operations performed in block 606, in response to receiving the RGS value from the RAT, the device processor uses the device processor to identify the RAT to associate the RGS value with the RAT. Can request information from the RAT. In some embodiments, the RAT may include information identifying itself along with the RGS value reported to the device processor.

  In optional block 608, the device processor can optionally associate the obtained RGS value with one or more attributes based on the time the RGS value was obtained in block 604. As described (see FIGS. 5A-5B), the device processor is responsible for the context information surrounding the RGS value based on various measurements, readings, etc. that occur at or before the time when the RGS value is obtained / received. / Attribute can be identified. For example, these attributes include the mobile communication device temperature, the crystal oscillator temperature, the current subscription of the RAT associated with the RGS value, the base station ID used to receive / determine the RGS value, and the RGS value. It may include one or more of time / time stamps obtained / obtained, current location / GPS coordinates of the mobile communication device, etc.

  In some embodiments, the RGS value may reflect the frequency error characteristics when the crystal oscillator on the mobile communication device is at a particular temperature. The operating frequency of the crystal oscillator can vary based on the temperature of the mobile communication device, so the device processor can determine the temperature of the mobile communication device when the RGS value is obtained and Associated with the RGS value, which can allow the device processor to make adjustments to the RGS value if the temperature of the mobile communication device changes at a later time.

  At block 610, the device processor may store the obtained RGS value and its association with the RGS value, such as in the data table described (eg, with reference to FIGS. 5A-5B). As a result of storing the RGS values and their associations / attributes, the device processor can quickly retrieve a particular RGS value associated with a particular RAT that is most useful / suitable for performing various operations on the RAT. Specifically, the device processor may request an entity (e.g., RAT, sleep controller, GPS module, etc.) based on the current conditions of the mobile communication device and / or the network that the mobile communication device is attempting to communicate with. The stored attribute associated with the RGS value can be utilized to select the RGS value that is most likely / reliable for use by. For example, in response to receiving a request for an RGS value from the requesting entity (see FIGS. 7A-7C), the device processor can determine the current temperature of the crystal oscillator and the current GPS coordinates of the mobile communication device. The RGS value with the stored association closest to the currently observed condition on the mobile communication device can be retrieved.

  FIG. 7A illustrates a method 700 for sending a stored RGS value associated with a RAT to a requesting entity, according to some embodiments. Method 700 may be performed by a processor (e.g., general purpose processor 206, baseband modem processor 216, crystal oscillator manager 230, crystal oscillator manager 230, another controller, and / or the like of FIG. 2) of a mobile communication device (e.g., mobile communication device 200 of FIG. 2). ). Operation of method 700 may implement an embodiment of operation of method 600 (see FIG. 6). Accordingly, with reference to FIGS. 1, 2, and 4-7, the device processor may begin performing the operations of method 700 in response to storing the RGS value and its association at block 610 of method 600. it can.

  At block 702, the device processor may monitor a request for an RGS value from a requesting entity on the mobile communication device. As described, the requesting entity calculates the RAT sleep duration based on the RAT associated with the RAT, the RAT associated with the RAT, which prepares to perform the acquire or reacquire operation based on the associated RGS value of the RAT. A sleep controller (see FIG. 10) that prepares to perform, and / or a RAT (see FIGS. 11-12) that prepares to perform inter-handover operation / RAT measurements. In some embodiments, the requesting entity can include a GPS receiver (eg, GPS module 234) that can utilize RGS values in receiving signals from GPS satellites.

  In decision block 704, the device processor may determine whether a request for RGS value has been received from the requesting entity, and no request for RGS value has been received (ie, decision block 704 = “No”). Meanwhile, the request for RGS values from the requesting entity at block 702 can continue to be monitored.

  In response to determining that a request for an RGS value from the requesting entity has been received (i.e., decision block 704 = “Yes”), the device processor may identify a RAT associated with the request at block 706. it can. In some embodiments, the device processor can determine the identity of the RAT associated with the request based on information included in the request. For example, a request from the RAT can include information identifying itself, and a request from the sleep controller can include information indicating the RAT that the sleep controller is attempting to calculate its sleep duration.

  In some embodiments, the device processor can identify the RAT associated with the request based on indirect information, such as by determining the operational status of each of the plurality of RATs on the mobile communication device. For example, the device processor may determine that a RAT has just been reactivated and may need to perform an acquisition / re-acquisition operation in the near future, based on that determination The RAT can be identified as likely to be related to the request.

  At block 708, the device processor stores the stored RGS value associated with the RAT identified at block 706, such as by performing a lookup in an associated data table (eg, data table 500) for the identified RAT. Can be taken out. In some embodiments of the operations performed in blocks 706, 708, the device processor may include at least one of a current subscription to the RAT and / or a base station, a current temperature of the crystal oscillator, a geographic location, etc. In addition, the RAT associated with the request can be identified. The device processor performs a lookup in an associated extended data table (e.g., data table 510) that can indicate a particular RGS value, thereby storing the stored RGS value associated with the RAT and the current RAT. Or at least one of subscription, base station identification, etc.

  In some embodiments of the operations performed at block 708, the device processor may retrieve the stored RGS value for use by the requesting entity such that the retrieved RGS value has a high confidence value. . In such embodiments, the device processor may store stored attributes associated with the stored RGS value (e.g., information associated with the RGS value when the RGS value was obtained) on the mobile communication device and / or It can be compared to the conditions currently observed / experienced / measured on a nearby mobile network (see FIG. 7B).

  In optional block 710, the device processor may adjust the RGS value retrieved in block 708 based on the change in at least one stored attribute associated with the retrieved RGS value. For example, since an RGS value may be particularly useful for a given temperature of the crystal oscillator, the device processor is associated with the RGS value that was retrieved when the retrieved RGS value was stored (e.g., With reference to the crystal temperature (in optional block 608 of method 600), the difference between the current crystal temperature and the referenced crystal temperature can be calculated. Based on the temperature difference, the device processor can adjust the RGS value to compensate for the effect of the temperature difference on the operating frequency of the crystal oscillator. This adjustment to the RGS value may be particularly useful when the crystal oscillator is a non-temperature compensated crystal oscillator. This is because the operating frequency of these crystals can vary greatly depending on temperature.

  The device processor may send the retrieved RGS value to the requesting entity at block 712, so that the requesting entity is very relevant and suitable for use with the RAT identified at block 706. It can be guaranteed to retrieve the RGS value. In some embodiments where the device processor adjusts the RGS value at optional block 710, the device processor may send at block 712 to the entity requesting the adjusted RGS value.

  The device processor can repeat the above operations in the loop by again monitoring the request for RGS values from the requesting entity at block 702.

  In some embodiments, in addition to receiving RGS values from the RAT, the device processor may also receive RGS values from a GPS module (eg, GPS module 234) on the mobile communication device. In such embodiments, one or more RGS values may be associated with the GPS module, such as by performing an action similar to that described with reference to method 700, and sent to the GPS module upon request. obtain. In some embodiments, the device processor may adjust the RGS value before sending the RGS value to the GPS unit / module to reflect time, temperature, geographic location, and other changes.

  FIG. 7B illustrates a method 720 for retrieving a stored RGS value associated with a RAT based on a confidence value of the stored RGS value, according to some embodiments. Method 720 may be implemented in a processor (e.g., general purpose processor 206, baseband modem processor 216, crystal oscillator manager 230, crystal oscillator manager 230, another controller, and / or the like in FIG. ).

  As explained, the RGS value reflects, among other things, the base station / network frequency error when the RGS value is received / obtained, taking into account the situation and / or condition combination observed at that time. Can do. For example, the RGS value can reflect the frequency error for a given temperature of a crystal oscillator of a base station on a particular mobile network (eg, GSM®) at a particular geographic location. Thus, RGS values may have particularly high utility under circumstances similar to or identical to the situations in which RGS values were first obtained / received. However, over time, the current conditions experienced / observed / measured on the mobile communication device will change, which may be appropriate / reliable for use taking into account the conditions in which the RGS value has changed. Degree or “confidence” may be affected. In the above example, the device processor can determine that the RGS value is less reliable / likelihood that the RGS value is useful, considering a substantial change in the crystal oscillator temperature.

  As a result, in some embodiments, the device processor may request that an RGS value be required to acquire a service, facilitate a handover operation, perform a sleep calculation, etc. based on the current conditions / situations of the mobile communication device. Changes in the conditions / states of the mobile communication device can be taken into account when determining a range that may be useful / useful for the mobile communication device.

  Operation of method 720 may implement an embodiment of the operation in block 708 of method 700 (see FIG. 7A). Accordingly, with reference to FIGS. 1, 2, and 4-7B, the device processor responsive to identifying the RAT associated with the request for RGS value at block 706 of method 700, the operation of method 720. Execution can begin.

  At block 721, the device processor stores a data table (e.g., FIG. 5A) that stores the association between the RGS value and the RAT, among other things, to identify the RGS value associated with the RAT identified at block 706 of the method 700. The group of RGS values associated with the RAT identified in block 706 of method 700 can be identified, such as by referring to data tables 500, 510) of FIG. 5B.

  At decision block 722, the device processor can determine whether there is at least one stored RGS value in the group of RGS values associated with the identified RAT. In response to determining that there is at least one stored RGS value associated with the identified RAT (ie, decision block 722 = “Yes”), the device processor associates the identified RAT with block 724. A confidence value can be determined for each stored RGS value in a group of RGS values to be performed. In some embodiments of the operations performed in block 724, the device processor may include a mobile communication device such as current time, crystal oscillator temperature, nearby base station, accessible mobile network, current geographic location / GPS coordinates, etc. Determining / observing / measuring various current conditions / situations, and storing the current conditions / situations associated with RGS values that reflect the historical conditions / situations that existed when the RGS values were observed / received Can be compared to the attribute. The confidence value may be based on this comparison, and the current condition / situation may indicate a range that matches or differs from the attribute associated with the RGS value. In other words, the confidence value can indicate how appropriate / reliable the RGS value is, as explained, given the changing conditions / situations, and the lower confidence value is the higher degree of confidence. Changes can be reflected, with higher confidence being able to indicate a lower degree of change.

  In some embodiments, the device processor can determine a confidence value for each attribute associated with the RGS value. For example, based on the current temperature of the crystal oscillator, there may be 80% confidence that the RGS value is useful / reliable, but given the current geographical location of the mobile communication device, the RGS value is useful. There can be 20% confidence of being / reliable.

  In some embodiments, the confidence value may be a value that collectively indicates the overall degree of change in all attributes associated with the RGS value (ie, a composite confidence value). For example, the confidence value may generally indicate that the RGS value has 90% confidence that it is useful / trustworthy given the current conditions / situations of the mobile communication device. In such an embodiment, the composite confidence value may be based on the individual confidence values of the conditions associated with the RGS value given the current conditions / situations.

  At decision block 726, the device processor determines whether the determined confidence of at least one stored RGS value in the group of RGS values associated with the identified RAT satisfies a confidence threshold. be able to. In other words, the device processor can determine whether there is an RGS value associated with the identified RAT having a confidence value greater than or equal to the confidence threshold.

  In some embodiments, the confidence threshold may be a minimum confidence value that the RGS value can be expected to be reliable or useful in obtaining the service. For example, RGS values with confidence values that do not satisfy the confidence threshold may not be particularly useful in facilitating inter-RAT measurements, handover operations, service acquisition / reacquisition, sleep timing programming, etc. . For example, a RAT that uses an RGS value that is particularly relevant to outdated or obsolete information is likely to be inaccurate given the current situation / condition of the mobile communication device, so that the service is acquired. May require a relatively long search window.

  In some embodiments of the operations performed at decision block 726, the confidence threshold may be an overall confidence threshold, and the device processor may generally use the RGS value. Can be compared with the overall confidence value or the composite confidence value of the RGS value.

  In some embodiments, the device processor can compare a confidence value for each attribute associated with the RGS value to a confidence threshold. In such an embodiment, the device processor may determine that the RGS value satisfies the confidence threshold when each confidence value (or a percentage of confidence values) satisfies the confidence threshold.

  In response to determining that the confidence of at least one stored RGS value in the group of RGS values associated with the identified RAT satisfies a confidence threshold (e.g., greater than or equal to) (Determination block 726 = “Yes”), the device processor may retrieve the stored RGS value having the greatest confidence value in the group of RGS values associated with the identified RAT at block 728. By retrieving the stored RGS value with the largest confidence value, the device processor is supplied to the requesting entity in block 712 of method 700, as described (see FIG. 7A). Can be guaranteed.

  In response to determining that there is no stored RGS value associated with the identified RAT (i.e., decision block 722 = “No”), or which stored in the group of RGS values associated with the identified RAT In response to determining that the RGS value also has no confidence value that satisfies the confidence threshold (ie, decision block 726 = “No”), the device processor associates the identified RAT with block 730. A substitute stored RGS value can be retrieved. In other words, the device processor requests if there is no RGS value associated with the identified RAT, or if no RGS value associated with the identified RAT has a confidence value that satisfies the confidence threshold. One can attempt to find another RGS value associated with another RAT that may be useful to the entity (see, eg, FIG. 7C).

  Regardless of whether the RGS value associated with the identified RAT is retrieved at block 728 or the substitute stored RGS value associated with another RAT is retrieved at block 730, the device processor optionally described As such, the retrieved RGS value may be adjusted based on a change in at least one stored attribute associated with the retrieved RGS value in optional block 710 of method 700. In some embodiments, by adjusting the retrieved RGS value, the device processor can increase the likelihood that the RGS value will be useful for the entity that it requires (ie, a confidence value for the RGS value).

  FIG. 7C illustrates a method 740 for retrieving a stored RGS value associated with an identified RAT subscription in the absence of an RGS value directly associated with the identified RAT, according to some embodiments. . Method 740 may include a processor (e.g., general purpose processor 206, baseband modem processor 216, crystal oscillator manager 230, crystal oscillator manager 230, another controller, and / or the like of FIG. 2) of a mobile communication device (e.g., mobile communication device 200 of FIG. 2). ). Operation of method 740 may implement an embodiment of operation of block 730 of method 720 (see FIG. 7B). Referring to FIGS. 1, 2, and 4-7C, the device processor is responsive to determining that there is no stored RGS value associated with the identified RAT (decision block 722 = “No”). The execution of the operations of method 740 can begin. In some embodiments, the device processor is responsive to determining that there are no RGS values associated with the identified RAT that satisfy the confidence threshold (ie, decision block 726 = “No”). Execution of 740 operations can begin.

  At block 742, the device processor is identified at block 706 of method 700, such as by performing a lookup operation within the RGS value association data table (e.g., data tables 500, 510 of FIGS. 5A-5B). You can try to identify the subscriptions associated with the RAT. In some embodiments, in response to determining that there is no RGS value associated with the identified RAT (or no RGS value with sufficient confidence value), the device processor associates with the identified RAT. One can attempt to retrieve the RGS values associated with the same subscription. In such an embodiment, RGS values related to the same subscription but related to different RATs are required in performing service acquisition / re-acquisition, inter-RAT measurement, handoff operation, sleep scheduling, GPS signal reception, etc. There may be a likelihood that it may be useful for the entity. For example, RGS values from different RATs that support the same subscription as the identified RAT, even if there is no RGS value associated with the identified RAT, or only a low confidence RGS value, Similar associations may be shared and therefore may be satisfactory RGS values. Accordingly, at block 744, the device processor can identify a group of RGS values associated with the subscription identified at block 742.

  At block 746, the device processor may be in a group of RGS values associated with the identified subscription, such as by performing an operation similar to the operation described with reference to block 724 of method 720 (see FIG. 7B). A confidence value can be determined for each stored RGS value. In other words, the device processor, as explained, is based on a comparison of the stored attributes associated with each RGS value and the current conditions / situations observed or measured on the mobile communication device, etc. It can be determined how likely each of the values is to be useful to the requesting entity.

  At decision block 748, the device processor is identified that satisfies a confidence threshold, such as by performing an operation similar to that described with reference to decision block 726 (see FIG. 7B) of method 720. It can be determined whether there are stored RGS values in the group of RGS values associated with the subscription. In response to determining that there is an RGS value in the group of RGS values associated with the identified subscription that satisfies the confidence threshold (i.e., decision block 748 = “Yes”), the device processor At block 756, the stored RGS value in that group having the largest confidence value in the group of RGS values associated with the identified subscription can be retrieved, thereby requesting at block 712 of method 700. The RGS value sent to the requesting entity is guaranteed to have the maximum likelihood that is useful for the requesting entity.

  In response to determining that there is no RGS value in the group of RGS values associated with the identified subscription that satisfies the confidence threshold (ie, decision block 748 = “No”), the device processor determines At block 750, it can be determined whether there are stored RGS values available on the mobile communication device. In other words, in response to determining that there are no RGS values in the group of RGS values associated with the identified subscription, the device processor identifies all other RGS values stored on the mobile communication device. You can try that.

  In response to determining that there is a stored RGS value available (ie, decision block 750 = “Yes”), the device processor retrieves the stored RGS value with the greatest confidence at block 754. be able to. In some embodiments, if there is no RGS value associated with an identified subscription with a large confidence value that satisfies a confidence threshold, the device processor is stored with the largest available confidence value. To retrieve the selected RGS value, one can select from any stored RGS value (ie, trying to associate with the identified subscription). For example, the device processor may not be associated with an identified subscription (and / or identified RAT) but may have an RGS value associated with a condition similar to the condition currently observed / measured on a mobile communication device. It can be taken out.

  In response to determining that no stored RGS value is available on the mobile communication device (i.e., decision block 750 = “No”), the device processor uses a mathematical model in block 752 to determine the RGS value. An approximation can be generated. In some embodiments, the device processor can rely on a mathematical model used to predict the frequency error based on the current temperature of the crystal oscillator using known methods. The device processor can rely on the mathematical model when, for example, there are no stored RGS values available on the mobile communication device.

  In response to retrieving the stored RGS value at block 756 or 754, the device processor, as described, may include at least one associated with the retrieved RGS value at optional block 710 of method 700 (see FIG. 7A). The retrieved RGS value can be adjusted based on changes in one stored attribute. Alternatively, in response to generating the RGS value approximation using the mathematical model in block 752, the device processor sends the approximated RGS value to the requesting entity in block 712 of method 700, as described. Can do.

  FIG. 8A illustrates a method 800 for associating an updated RGS value with a RAT and storing the updated RGS value for later use by or for that RAT, according to some embodiments. . Method 800 may be performed by a processor (e.g., general purpose processor 206, baseband modem processor 216, crystal oscillator manager 230, crystal oscillator manager 230, another controller, and / or the like of FIG. 2) of a mobile communication device (e.g., mobile communication device 200 of FIG. 2). ). Operation of method 800 may implement an embodiment of the operation of method 600 (see FIG. 6). Thus, with reference to FIGS. 1, 2, and 4-8A, the device processor initiates execution of the operations of method 800 in response to storing the RGS value and its association at block 610 of method 600. Can do.

  In block 802, the device processor may network the RAT for frequency error, such as by detecting when the RAT performs a reselection operation to camp on different cells / base stations that may have different frequency errors. Changes in conditions can be monitored. In some embodiments of the operation of block 802, the device processor may receive a communication or signal received directly from a particular RAT (e.g., the signaling of FIG. 4) indicating that the RAT has received an updated RGS value. 403, 405) can be monitored.

  In decision block 804, the device processor can determine if there is a change in RAT network conditions related to frequency error and unless there is a change in RAT network conditions related to frequency error (i.e., decision block 804 = “No” ”) Can continue to monitor for changes in RAT network conditions at block 802.

  In response to determining that there has been a change in the RAT network conditions with respect to the frequency error (i.e., decision block 804 = “Yes”), the device processor, in block 806, based on the current network conditions of the RAT, the RAT The updated RGS value of can be determined. For example, the device processor can compare the frequency of communications received from the RAT base station with the expected frequency, and based on that comparison, an updated RGS value that reflects the base station's current frequency error. Can be derived. In some embodiments, the device processor determines the current base station frequency errors of the RAT and adjusts these frequency errors based on the operating frequency of the crystal oscillator at the current temperature of the mobile communication device. Can calculate the updated RGS value.

  At block 808, the device processor may associate the updated RGS value with the RAT, such as by replacing the previous RGS value associated with the RAT with the updated RGS value in the RGS value association data table. . In some embodiments, the device processor may, for example, associate the updated RGS value with the current subscription of the RAT and the current base station of the RAT. Further, in optional block 810, the device processor may associate the updated RGS value with at least one current attribute based on the time at which the updated RGS value was determined in block 806. For example, at a later time, if the device temperature changes and affects the crystal oscillator's operating frequency, the device processor can adjust the updated RGS value so that the current temperature of the mobile communication device And the temperature can be associated with the updated RGS value.

  In block 812, the device processor stores the updated RGS value in memory and updates the association of the updated RGS value maintained in a data table maintained in memory (eg, memory 214). The updated RGS value and its association to the RAT (and optionally an association with at least one current attribute) can be stored.

  The device processor can repeat the above operations in the loop by again monitoring the change in RAT network conditions for frequency error at block 802.

  FIG. 8B illustrates a method 820 for modifying a stored RGS based on an updated RGS value determined based on current network conditions, according to some embodiments. Method 820 may be implemented in a processor (e.g., general purpose processor 206, baseband modem processor 216, crystal oscillator manager 230, crystal oscillator manager 230, another controller, and / or the like in FIG. 2) of a mobile communication device (e.g., mobile communication device 200 of FIG. 2). ).

  In some embodiments (eg, described with reference to FIG. 8A), the device processor may receive / determine an updated RGS value for the RAT based on current network conditions. However, updated RGS values may sometimes reflect false or inaccurate information that may be of little use in compensating for base station frequency errors. For example, the base station may temporarily report inaccurate frequency error measurements due to processing errors in the mobile network. To protect against the possibility that the updated RGS value contains inaccurate or fake information, the device processor automatically replaces the existing RGS value (e.g. described with reference to Figure 8A). Instead, various operations within the method 820 can be performed to modify an existing stored RGS value using the updated RGS value.

  With reference to FIGS. 1, 2, and 4-8B, operation of method 820 may implement an embodiment of operation of method 600 (see FIG. 6). Accordingly, the device processor may begin performing the operations of method 820 in response to storing the RGS value and its association at block 610 of method 600.

  The device processor may perform operations in blocks 802 through 806 that are the same as or similar to the operations described with reference to blocks 802 through 806 (see FIG. 8A) of method 800. In other words, the device processor can monitor the change in RAT network conditions for frequency error at block 802 and can determine if there is a change in RAT network conditions for frequency error at decision block 804. In response to determining that there is (ie, decision block 804 = “Yes”), at block 806, the device processor can determine an updated RGS value for the RAT based on current network conditions.

  At block 822, the device processor stores the associated RAT, such as by accessing the associated data table and performing a lookup operation in the data table to identify the RGS value associated with the RAT. RGS value can be retrieved.

  At block 824, the device processor may change the stored RGS value based on the updated RGS value. In some embodiments of the operations performed in block 824, the device processor may retrieve the retrieved RGS value, such as by replacing the retrieved RGS value with an average of the updated RGS value. Adjust the RGS value so that the updated RGS value can substantially degrade the usefulness of the RGS value (i.e., due to inaccuracies introduced with the updated RGS value). Can be limited.

  In some embodiments, the device processor may maintain one or more previous versions of the RGS value, including the most recently received / determined RGS value. In response to the determination of the updated RGS value in block 806, the device processor can retrieve one or more previous versions of the RGS value, the previously stored version of the RGS value and the updated RGS value. Based on the value, a new RGS value can be calculated for use by one or more components on the mobile communication device. For example, the new RGS value may be the average value of the updated RGS value and the four previously stored versions of the RGS value. By utilizing multiple previously stored versions of the RGS value, the device processor can further reduce the likelihood that the updated RGS value will substantially impair the usefulness of the RGS value.

  In optional block 826, the device processor may identify at least one attribute associated with the updated RGS value based on the time at which the updated RGS value was determined in block 806. As explained, the device processor is on the mobile communication device such as the device / crystal oscillator temperature, geographic location, active subscription, base station, etc. that was associated with the RAT when the updated RGS value was determined. At least one attribute can be identified based on various factors or situations currently experienced.

  In optional block 828, the device processor changes at least one attribute associated with the changed RGS value based on at least one attribute associated with the updated RGS value identified in optional block 826. Can do. In some embodiments, changing the association of the stored RGS value may include changing the device temperature value associated with the stored RGS value to the device temperature value associated with the previously stored device temperature value and the updated RGS value. Changing the entry in the association data table, such as by replacing with the average device temperature with the value, can be included. By changing (rather than replacing / overwriting) the conditions, characteristics, status, etc. associated with the stored RGS value, the device processor can store the false information about the updated RGS value. It can be ensured that the usefulness of is not substantially impaired.

  The device processor may repeat the above operations of method 820 in a loop by again monitoring the change in RAT network conditions for frequency error at block 802.

  FIG. 9 illustrates an implementation method 900 for configuring a RAT to sleep during a time period based on an RGS value associated with the RAT, according to some embodiments. Method 900 may be performed by a processor (e.g., general purpose processor 206, baseband modem processor 216, crystal oscillator manager 230, crystal oscillator manager 230, another controller, and / or the like of FIG. 2) of a mobile communication device (e.g., mobile communication device 200 of FIG. 2). ). Referring to FIGS. 1, 2, and 4-9, the operation of method 900 may implement an embodiment of the operation of method 600 (see FIG. 6). Accordingly, the device processor may begin performing the operations of method 900 in response to storing the RGS value and its association at block 610 of method 600.

  In block 902, the device processor can monitor sleep notifications from the RAT. In some embodiments, the sleep notification may be a signal or other indication sent from the RAT indicating that the RAT is about to enter sleep or idle mode. For example, the first RAT is shared with the second RAT in anticipation of a temporary disruption of the first RAT access to the RF resources shared on the DSDS communication device in favor of the second RAT. A notification may be sent to the device processor indicating that the first RAT may be in sleep / idle mode while having access to RF resources. In some embodiments, rather than receiving a sleep notification directly from the RAT, the device processor may monitor the RAT performance schedule and / or indicate that the RAT may need to perform a sleep operation. It can be determined when the RAT may need to perform sleep / idle mode operation, such as by determining when the situation shown occurs on the mobile communication device.

  In decision block 904, the device processor can determine whether a sleep notification has been received from the RAT and unless a sleep notification is received from the RAT (ie, while decision block 904 = “No”). At block 902, sleep notifications from the RAT may continue to be monitored.

  In response to determining that a sleep notification has been received from the RAT (ie, decision block 904 = “Yes”), the device processor may retrieve an RGS value associated with the notifying RAT at block 906. In some embodiments, the device processor identifies the reporting RAT based on the request and / or based on indirect information received from other components on the mobile communication device that identifies the reporting RAT. Can do.

  In optional block 710, the device processor may change the at least one stored attribute associated with the retrieved RGS value by performing an operation similar to that described in optional block 710 of method 700. Based on this, the received RGS value can be adjusted. For example, the device processor can adjust the received RGS value based on the temperature change of the mobile communication device to compensate for the effect of the temperature change on the operating frequency of the crystal oscillator.

  At block 910, the device processor may determine a time period based on the sleep notification and the received RGS value. In some embodiments of the operations performed in block 910, the device processor converts the RGS value obtained in block 906 (and optionally adjusted in optional block 908) to a time domain value. The sleep duration of the RAT to be notified can be determined based on the time domain value. In some embodiments, the device processor may configure the notifying RAT to sleep for the time period determined in block 910. In some embodiments, rather than configuring a RAT that signals to sleep for a determined time period, the notifying RAT is part of its normal operation without specific instructions or assistance from the device processor. The sleep operation can be started independently.

  In block 912, the device processor wakes up at the expiration of the determined time period, such as by counting down from the time when the RAT to notify starts the sleep operation until the time period determined in block 910 elapses. RAT can be configured.

  The device processor may repeat the above operations of method 900 in a loop by monitoring again for sleep notifications from the RAT at block 902.

  FIG. 10 illustrates a method 1000 for configuring a RAT to perform an acquisition or reacquisition operation by utilizing an RGS value associated with the RAT, according to some embodiments. The method 1000 includes a processor (e.g., general purpose processor 206, baseband modem processor 216, crystal oscillator manager 230, crystal oscillator manager 230, another controller, and / or the like of FIG. 2) of a mobile communication device (e.g., mobile communication device 200 of FIG. 2). ). With reference to FIGS. 1, 2, and 4-10, the operation of method 1000 may implement an embodiment of the operation of method 600 (see FIG. 6). Accordingly, the device processor may begin performing the operations of method 1000 in response to storing the RGS value and its association at block 610 of method 600.

  In block 1002, the device processor may monitor the RAT that is about to perform network acquisition or network reacquisition. In some embodiments, the device processor may need to immediately perform an acquisition operation in order for the RAT to establish service with the base station, indicating that the RAT has recently been activated. Or a signal indicating that the RAT was recently reactivated from sleep or idle mode, RAT performs a reacquisition operation to re-establish service with the base station lost during sleep / idle mode A signal can be monitored to indicate that it may be necessary.

  In decision block 1004, the device processor can determine whether the RAT is about to perform a network acquisition operation or a network reacquisition operation, unless the RAT is about to perform a network acquisition operation or a network reacquisition operation (i.e., , Decision block 1004 = “No”), at block 1002, the RAT attempting to perform the network acquisition operation or the network reacquisition operation can continue to be monitored.

  In response to determining that the RAT is about to perform a network acquisition or network reacquisition operation (i.e., decision block 1004 = “Yes”), the device processor, in block 1006, performs a network acquisition operation or a network reacquisition operation. The stored RGS value associated with the RAT that is trying to execute can be obtained. As described, the device processor uses an associated data table (e.g., FIGS. 5A-5B) stored in memory to identify the RGS value associated with the RAT that is performing the acquire / re-acquire operation. A lookup can be performed in the data tables 500, 510) described with reference, and the device processor can retrieve its RGS value from memory.

  In optional block 710, the device processor stores at least one stored associated with the retrieved RGS value, such as by performing an operation similar to the operation in optional block 710 of method 700 (see FIG. 7). The retrieved RGS value can be adjusted based on the attribute change. For example, the device processor compensates for any changes in the temperature of the mobile communication device that may have occurred since the RGS value was initially obtained (see, for example, block 604 of method 600) and associated with the RAT. Therefore, the RGS value retrieved in block 1006 can be adjusted.

  In block 1010, the device processor configures the RAT to perform a network acquisition or network reacquisition operation based on the RGS value obtained in block 1006 (and optionally adjusted in optional block 710). can do. In some embodiments, the device processor can utilize the obtained RGS value to determine the frequency required for the RAT to communicate with a nearby base station and receive service from that base station. .

  The device processor may repeat the above operations of method 1000 by again monitoring the RAT that is attempting to perform network acquisition or network reacquisition at block 1002.

  FIG. 11 illustrates a method 1100 for configuring a RAT to perform a handover operation to an identified base station by utilizing an RGS value associated with the identified base station, according to some embodiments. Show. The method 1100 includes a processor (e.g., general purpose processor 206, baseband modem processor 216, crystal oscillator manager 230, crystal oscillator manager 230, another controller, and / or the like of FIG. 2) of a mobile communication device (e.g., mobile communication device 200 of FIG. 2). ). With reference to FIGS. 1, 2, and 4-11, the operation of method 1100 may implement an embodiment of the operation of method 600 (see FIG. 6). Accordingly, the device processor may begin performing the operations of method 1100 in response to storing the RGS value and its association at block 610 of method 600.

  In block 1102, the device processor may monitor a handover notification from the RAT. In some embodiments, the device processor performs a handover operation where the RAT is from a first base station to a second base station (eg, from the first base station 130 of FIG. 1 to the second base station 140). Can be monitored for a signal indicating that it is or is about to execute. In some embodiments, the device processor can indicate the likelihood that the RAT performs a handover operation, such as, in addition to or instead of, a low received signal strength or a low quality of service from the first base station. Signals or conditions can be monitored.

  In decision block 1104, the device processor can determine whether a notification from the RAT has been received, and unless a handover notification is received from the RAT (ie, decision block 1104 = “No”), the RAT in block 1102. Can continue to monitor handover notifications from

  In response to determining that a handover notification has been received from the RAT (ie, decision block 1104 = “Yes”), the device processor may identify a base station associated with the handover operation at block 1106. In some embodiments, the device processor may directly select a base station from a handover notification, such as may occur when the RAT directly identifies the base station that the RAT intends to acquire or is trying to acquire. Can be identified. In some embodiments, the device processor can identify a base station based on inter-RAT measurement results indicating that a base station using a particular RAT can provide better service.

  At block 1108, the device processor may store an association data table (e.g., the data table 500 described with reference to FIGS. 5A-5B) stored in memory to identify the RGS value associated with the identified base station. , 510) and the stored RGS associated with the base station identified in block 1106, such as by performing a lookup in memory and retrieving the RGS value associated with the base station from memory (e.g., memory 214). The value can be retrieved.

  In optional block 710, the device processor may use the retrieved RGS value, such as by performing an operation similar to that described above with reference to optional block 710 of method 700 (see, eg, FIG. 7). The retrieved RGS value may be adjusted based on a change in the associated at least one stored attribute. In other words, the device processor was retrieved at block 1108 to compensate for any changes in mobile communication device conditions / situations that may have occurred since the RGS value was first obtained and stored. The RGS value can be adjusted. For example, the device processor can adjust the retrieved RGS value based on the change in temperature of the crystal oscillator.

  At block 1110, the device processor utilizes the RGS value retrieved at block 1108 (and optionally adjusted at optional block 710) to perform a handover operation to the identified base station. A RAT to be notified can be configured. In some embodiments, the device processor communicates with the identified base station with the RAT that it advertises and uses the obtained RGS value to determine the frequency required to receive service from that base station. be able to.

  The device processor may repeat the above operations of method 1100 in a loop by monitoring again for handover notifications from the RAT at block 1102.

  FIG. 12 illustrates a method 1200 for configuring a first RAT to perform an inter-RAT measurement of a second RAT by utilizing an RGS value associated with the second RAT, according to some embodiments. Show. The method 1200 includes a processor (e.g., the general purpose processor 206, baseband modem processor 216, crystal oscillator manager 230, crystal oscillator manager 230, another controller, and / or the like of the mobile communication device (e.g., the mobile communication device 200 of FIG. 2). ). Referring to FIGS. 1, 2, and 4-12, the operation of method 1200 may implement an embodiment of the operation of method 600 (see FIG. 6). Accordingly, the device processor may begin performing the operations of method 1200 in response to storing the RGS value and its association at block 610 of method 600.

  At block 1202, the device processor determines from the first RAT that the first RAT is or will perform an inter-RAT measurement, such as by monitoring indirect or direct notification from the RAT. Can be monitored for inter-RAT measurement notifications.

  In decision block 1204, the device processor can determine whether an inter-RAT measurement notification has been received from the first RAT, and unless an inter-RAT measurement notification has been received from the first RAT (i.e., the decision block). 1204 = “No”), the inter-RAT measurement notification from the first RAT may continue to be monitored at block 1202.

  In response to determining that an inter-RAT measurement notification has been received from the first RAT (i.e., decision block 1204 = “Yes”), the device processor in block 1206, as part of the inter-RAT measurement, the first A second RAT that the RAT measures can be identified. In some embodiments, the device processor can identify the second RAT directly from the inter-RAT measurement notification.

  At block 1208, the device processor may associate data tables (e.g., the data table 500 described with reference to FIGS. 5A-5B) stored in memory to identify the RGS value associated with the second RAT. 510) stored in association with the second RAT identified in block 1206, such as by performing a lookup in 510) and retrieving an RGS value associated with the base station from memory (e.g., memory 214). RGS value can be retrieved.

  In optional block 710, the device processor may use the retrieved RGS value, such as by performing an operation similar to that described above with reference to optional block 710 of method 700 (see, eg, FIG. 7). The RGS value retrieved at block 1208 may be adjusted based on the change in the associated at least one stored attribute. In other words, the device processor was retrieved at block 1208 to compensate for any changes in mobile communication device conditions / situations that may have occurred since the RGS value was first obtained and stored. The RGS value can be adjusted. For example, the device processor can adjust the retrieved RGS value based on the change in temperature of the crystal oscillator.

  In block 1210, the device processor first uses the RGS value retrieved in block 1208 (and optionally adjusted in optional block 710) to perform the inter-RAT measurement of the second RAT. One RAT can be configured.

  The device processor may repeat the above operations of method 1200 in a loop by again monitoring the inter-RAT measurement notification from the first RAT at block 1202.

  Various embodiments may be implemented in any of a variety of mobile communication devices, an example of which mobile communication device (eg, mobile communication device 1300) is shown in FIG. According to various embodiments, the mobile communication device 1300 can be similar to the mobile communication devices 110, 120, 200 described above with reference to FIGS. Accordingly, the mobile communication device 1300 can implement the methods 600, 700, 720, 740, 800, 820, 900, 1000, 1100, 1200 of FIGS.

  Mobile communication device 1300 can include a processor 1302 coupled to a touch screen controller 1304 and an internal memory 1306. The processor 1302 can be one or more multi-core integrated circuits designed for general or specific processing tasks. The internal memory 1306 can be volatile memory or non-volatile memory, and can be secure memory and / or encrypted memory, unsecure memory and / or unencrypted memory, or any combination thereof. . Touch screen controller 1304 and processor 1302 may also be coupled to a touch screen panel 1312, such as a resistance sensitive touch screen, a capacitance sensitive touch screen, an infrared sensitive touch screen, and the like. Further, the display of the mobile communication device 1300 need not have touch screen functionality.

  The mobile communication device 1300 may include one or more wireless signal transceivers 1308a, 1308b (eg, Peanut, Bluetooth®, Zigbee, Wi-Fi) for sending and receiving communications coupled to each other and / or to the processor 1302. -Fi, RF radio) and one or more antennas 1310, 1311. Transceivers 1308a, 1308b and antennas 1310, 1311 may be used with the circuitry described above to implement various wireless transmission protocol stacks and interfaces. Mobile communication device 1300 may include one or more SIM cards (eg, SIM 1319) coupled to transceivers 1308a, 1308b and / or processor 1302 and configured as described above. The mobile communication device 1300 is one or more cellular network wireless modems coupled to a processor 1302 and antennas 1310, 1311 that enable communication over two or more cellular networks via two or more radio access technologies. A chip 1316 can be included.

  Mobile communication device 1300 can include a peripheral device connection interface 1318 coupled to processor 1302. Peripheral device connection interface 1318 can be configured independently to accept one type of connection, or it can accept various types of physical and communication connections, including general or proprietary, such as USB, FireWire, Thunderbolt, or PCIe. Can be configured to accept. Peripheral device connection interface 1318 may also be coupled to a similarly configured peripheral device connection port (not shown).

  The mobile communication device 1300 can also include a speaker 1314 for providing audio output. The mobile communication device 1300 can also include a housing 1320 constructed of plastic, metal, or a combination of materials to include all or part of the components discussed herein. Mobile communication device 1300 can include a power source 1322 coupled to a processor 1302, such as a disposable battery or a rechargeable battery. A rechargeable battery may also be coupled to the peripheral device connection port to receive charging current from a power source external to the mobile communication device 1300. The mobile communication device 1300 can also include a physical button 1324 for receiving user input. The mobile communication device 1300 can also include a power button 1326 for turning the mobile communication device 1300 on and off.

  The foregoing method descriptions and process flow diagrams are provided merely as illustrative examples and are not intended to require or imply that the steps of the various embodiments must be performed in the order presented. . As will be appreciated by those skilled in the art, the order of the steps in the foregoing embodiments may be performed in any order. Words such as “thereafter”, “then”, “next” are not intended to limit the order of the steps, these words are simply a description of the method Used to guide readers through. Moreover, any reference to an element in a claim in the singular, for example using the article “a”, “an”, or “the” should not be construed as limiting the element to the singular.

  Various exemplary logic blocks, modules, circuits, and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware, computer software, or a combination of both. To clearly illustrate this interchangeability of hardware and software, various illustrative components, blocks, modules, circuits, and steps have been described above generally in terms of their functionality. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the overall system. Those skilled in the art can implement the described functionality in a manner that varies from one specific application to another, but such implementation decisions should not be construed as causing deviations from the scope of the present invention. .

  The hardware used to implement the various exemplary logic, logic blocks, modules, and circuits described in connection with aspects disclosed herein includes general purpose processors, digital signal processors (DSPs). ), Application specific integrated circuit (ASIC), field programmable gate array (FPGA) or other programmable logic device, discrete gate logic or transistor logic, discrete hardware components, or perform the functions described herein Can be implemented or implemented using any combination thereof designed. A general purpose processor may be a microprocessor, but in the alternative, the processor may be any conventional processor, controller, microcontroller, or state machine. The processor may also be implemented as a combination of computing devices, such as a combination of DSP and microprocessor, multiple microprocessors, one or more microprocessors associated with a DSP core, or any other such configuration. . In the alternative, some steps or methods may be performed by circuitry specific to a given function.

  In one or more exemplary aspects, the functions described may be implemented in hardware, software, firmware, or any combination thereof. When implemented in software, the functions may be stored as one or more instructions or code on a non-transitory computer-readable storage medium or non-transitory processor-readable storage medium. The method or algorithm steps disclosed herein may be embodied in a processor-executable software module that may reside on a non-transitory computer-readable storage medium or a non-transitory processor-readable storage medium. The non-transitory computer readable storage medium or non-transitory processor readable storage medium may be any storage medium that can be accessed by a computer or processor. By way of example, and not limitation, such non-transitory computer readable storage media or non-transitory processor readable storage media may be RAM, ROM, EEPROM, flash memory, CD-ROM or other optical disk storage, magnetic disk storage or other It may include a magnetic storage device or any other medium that can be used to store desired program code in the form of instructions or data structures and that can be accessed by a computer. Discs (disks and discs) used in this specification are compact discs (CDs), laser discs (discs), optical discs (discs), digital versatile discs (DVDs), floppy discs (disks). ), And a Blu-ray disc, the disk typically reproduces data magnetically, and the disc optically reproduces data using a laser. Combinations of the above are also included within the scope of non-transitory computer-readable storage media and non-transitory processor-readable storage media. Further, the operation of the method or algorithm may be incorporated into a non-transitory processor-readable storage medium and / or a non-transitory computer-readable storage medium and / or instructions or such code on a computer program product. It can exist as any combination or set of instructions.

  The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. . Accordingly, the present invention is not intended to be limited to the embodiments shown herein, but is most consistent with the following claims and the principles and novel features disclosed herein. A wide range should be given.

100 communication system
102 First mobile network
104 Second mobile network
110 First mobile communications device
120 Second mobile communication device
130 First base station
132 Cellular connection
134 Wired connection
140 Second base station
142 Cellular connection
144 Wired connection
152 Wireless connection
150 peripheral devices
160 Wireless access point
162 Wireless connection
164 Internet
166 Wired connection
200 mobile communication devices
202a First SIM interface
202b Second SIM interface
204a First identification module SIM-1
204b Second identification module SIM-2
206 General-purpose processor
208 coder / decoder (codec)
210 Speaker
212 microphone
214 memory
216 baseband modem processor
218a RF resources
218b RF resources
220a Second wireless antenna
220b second wireless antenna
224 keypad
226 touch screen display
230 Crystal Oscillator Manager
232 sleep controller
234 Global Positioning System (GPS) Module
236 Temperature sensor
300 Figure
302 1st RAT
304 sleep controller
306 Crystal Oscillator Manager
308 2nd RAT
310 signaling
312 Acquisition
314 Signaling
315 operation
316 signaling
317 operation
318 signaling
320 signaling
322 Operation
324 operation
326 Wake-up signal
328 signaling
330 Re-acquisition action
400 call flow diagram
402 signaling
403 signaling
404 operation
405 signaling
406 Operation
407 signaling
408 operation
412 Wake-up signal
414 signaling
416 Re-acquisition action
500 data tables
510 Data table
600 methods
700 methods
720 method
740 methods
800 methods
820 method
900 Implementation Method
1000 methods
1100 method
1200 methods
1300 Mobile communication devices
1302 processor
1304 Touch screen controller
1306 Internal memory
1308a radio signal transceiver
1308b radio signal transceiver
1310 Antenna
1311 Antenna
1312 touch screen panel
1314 Speaker
1316 Cellular network wireless modem chip
1318 Peripheral device connection interface
1319 SIM
1320 housing
1322 power supply
1324 button
1326 Power button
BB1 baseband processor
BB2 baseband processor

Claims (30)

A method implemented by a mobile communication device for improving multiple radio access technology (RAT) performance on a mobile communication device, comprising:
Obtaining a recent good system (RGS) value for each of the plurality of RATs;
Associating the obtained RGS value with each of the plurality of RATs;
Storing the obtained RGS value and the association of the obtained RGS value. Further comprising associating the obtained RGS value with at least one attribute based on the time when the RGS value of the plurality of RATs is obtained;
The attribute includes one of the temperature of the mobile communication device, the temperature of the crystal oscillator of the mobile communication device, a base station identification, a subscription identification, a geographical location of the mobile communication device, a service network identification, and a timestamp. The method of claim 1 comprising. Identifying a RAT in the plurality of RATs associated with a request for an RGS value from a requesting entity;
Retrieving a stored RGS value associated with the identified RAT;
2. The method of claim 1, further comprising: sending the retrieved RGS value to the requesting entity. Retrieving a stored RGS value associated with the identified RAT comprises:
Identifying a first group of RGS values associated with the identified RAT;
Determining a confidence value for each RGS value in the first group of RGS values;
Retrieving a stored RGS value in the first group of RGS values having the largest confidence value in the first group of RGS values.   Further comprising adjusting the retrieved RGS value based on a change in at least one stored attribute associated with the retrieved RGS value, and sending the retrieved RGS value to the requesting entity. 4. The method of claim 3, comprising sending the adjusted RGS value to the requesting entity.   The step of adjusting the retrieved RGS value based on a change in at least one stored attribute associated with the retrieved RGS value includes the retrieving based on a temperature change associated with the retrieved RGS value. 6. The method of claim 5, comprising adjusting the measured RGS value. Retrieving a stored RGS value associated with the identified RAT comprises:
Identifying a first group of RGS values associated with the identified RAT;
Determining whether there is at least one stored RGS value in the first group of RGS values;
Retrieving a surrogate stored RGS value not associated with the identified RAT in response to determining that there is no RGS value in the first group of RGS values. Method. In response to determining that there is at least one RGS value in the first group of RGS values, at least one RGS value in the first group of RGS values satisfies a confidence threshold. Determining whether to have a confidence value;
In response to determining that any RGS value in the first group of RGS values associated with the identified RAT does not have a confidence value that satisfies the confidence threshold, the identified RAT. Retrieving a stored stored RGS value that is not related to
In response to determining that an RGS value in the first group of RGS values associated with the identified RAT has a confidence value that satisfies the confidence threshold, the first of the RGS values. 8. The method of claim 7, further comprising: retrieving a stored RGS value in the first group of RGS values having the largest confidence value in the group. Retrieving a surrogate stored RGS value not associated with the identified RAT comprises:
Identifying a subscription associated with the identified RAT;
Identifying a second group of RGS values associated with the identified subscription;
And determining a confidence value for each stored RGS value in the second group of RGS values. Determining whether there are stored RGS values in the second group of RGS values that satisfy a confidence threshold; and
In response to determining that there is a stored RGS value in the second group of RGS values that satisfies the confidence threshold, a maximum confidence value in the second group of RGS values is determined. 10. The method of claim 9, further comprising: retrieving a stored RGS value in the second group of having RGS values. In response to determining that there are no stored RGS values in the second group of RGS values associated with the identified subscription that satisfy the confidence threshold, on the mobile communication device Determining whether there is a stored stored RGS value; and
In response to determining that there is a stored RGS value available on the mobile communication device, retrieving a stored RGS value usable on the mobile communication device having a maximum confidence value;
11. The method of claim 10, further comprising: generating a RGS value approximation using a mathematical model in response to determining that there are no stored RGS values available on the mobile communication device. Determining an updated RGS value of the RAT based on a current network condition of the RAT of the plurality of RATs;
Associating the updated RGS value with the RAT;
The method of claim 1, further comprising: storing the association of the updated RGS value with the updated RGS value and the RAT.   Further comprising associating the updated RGS value with at least one current attribute based on a time at which the updated RGS value is determined, the updated RGS value and the updated RAT. The step of storing the association of RGS values includes the updated RGS value, the association of the updated RGS value with the RAT, and the updated RGS value with the at least one current attribute. 13. The method of claim 12, comprising storing the association. Determining an updated RGS value of the RAT based on a current network condition of the RAT of the plurality of RATs;
Retrieving a stored RGS value associated with the RAT;
The method of claim 1, further comprising: changing the stored RGS value associated with the RAT based on the updated RGS value. Identifying at least one attribute associated with the updated RGS value based on a time at which the updated RGS value is determined;
15. The method of claim 14, further comprising: modifying at least one attribute associated with the modified RGS value based on the at least one attribute associated with the updated RGS value. Retrieving an RGS value associated with the RAT in response to receiving a sleep notification from a RAT in the plurality of RATs;
Determining a time period based on the sleep notification and the retrieved RGS value;
2. The method of claim 1, further comprising: configuring the RAT to wake up when the time period expires.   Adjusting the retrieved RGS value based on a change in at least one stored attribute associated with the retrieved RGS value, and based on the sleep notification and the retrieved RGS value; 17. The method of claim 16, wherein determining a time period includes determining the time period based on the sleep notification and the adjusted RGS value. Determining that a RAT in the plurality of RATs is performing one of a network acquisition operation and a network reacquisition operation;
Retrieving an RGS value associated with the RAT;
2. The method of claim 1, further comprising: configuring the RAT to perform the one of the network acquisition operation and the network reacquisition operation based on the retrieved RGS value.   Adjusting the retrieved RGS value based on a change in at least one stored attribute associated with the retrieved RGS value, the network acquisition operation based on the retrieved RGS value; And configuring the RAT to perform the one of the network reacquisition operations, based on the adjusted RGS value, the network acquisition operation and the one of the network reacquisition operations. 19. The method of claim 18, comprising configuring the RAT to perform one. Retrieving an RGS value associated with the base station in response to determining that a RAT in the plurality of RATs is about to perform a handover operation to the base station;
2. The method of claim 1, further comprising: configuring the RAT to perform the handover operation to the base station based on the retrieved RGS value.   Adjusting the retrieved RGS value based on a change in at least one stored attribute associated with the retrieved RGS value, to the base station based on the retrieved RGS value; The step of configuring the RAT to perform the handover operation of the method includes the step of configuring the RAT to perform the handover operation to the base station based on the adjusted RGS value. Item 20. The method according to Item 20. In response to determining that the first RAT in the plurality of RATs is performing inter-RAT measurement of the second RAT in the plurality of RATs, retrieves an RGS value associated with the second RAT. Steps,
2. The method of claim 1, further comprising: configuring the first RAT to perform the inter-RAT measurement of the second RAT based on the retrieved RGS value.   Further comprising adjusting the retrieved RGS value based on a change in at least one stored attribute associated with the retrieved RGS value, and based on the retrieved RGS value, the second The step of configuring the first RAT to perform the inter-RAT measurement of RAT, based on the adjusted RGS value, to perform the inter-RAT measurement of the second RAT. 23. The method of claim 22, comprising configuring the RAT of Memory,
Radio frequency (RF) resources,
A processor coupled to the memory, the RF resource, and at least one subscriber identity module (SIM), the processor comprising:
Obtaining a recent good system (RGS) value for each of multiple radio access technologies (RATs);
Associating the obtained RGS value with each of the plurality of RATs;
Storing the obtained RGS value and the association of the obtained RGS value in the memory;
Mobile communication device. The processor is further configured to associate the obtained RGS value with at least one attribute based on a time at which the RGS values of the plurality of RATs are obtained;
The attribute includes one of the temperature of the mobile communication device, the temperature of the crystal oscillator of the mobile communication device, a base station identification, a subscription identification, a geographical location of the mobile communication device, a service network identification, and a timestamp. Including,
25. A mobile communication device according to claim 24. The processor is
Identifying a RAT of the plurality of RATs associated with a request for an RGS value from a requesting entity;
Retrieving a stored RGS value associated with the identified RAT from the memory;
25. The mobile communication device of claim 24, further configured to: send the retrieved RGS value to the requesting entity. The processor is
Adjusting the retrieved RGS value based on a change in at least one stored attribute associated with the retrieved RGS value;
27. The mobile communication device of claim 26, further configured to: send the adjusted RGS value to the requesting entity. The processor is
Determining an updated RGS value of the RAT based on a current network condition of the RAT of the plurality of RATs;
Associating the updated RGS value with the RAT;
25. The mobile communication device of claim 24, further configured to: store in the memory the association of the updated RGS value and the updated RGS value with the RAT. A non-transitory processor readable storage storing processor executable instructions configured to cause a processor of a mobile communication device to perform operations on the mobile communication device to improve performance of a plurality of radio access technologies (RATs) A medium, wherein the action is
Obtaining a recent good system (RGS) value for each of the plurality of RATs;
Associating the obtained RGS value with each of the plurality of RATs;
A non-transitory processor readable storage medium comprising: storing the obtained RGS value and the association of the obtained RGS value. Means for obtaining a recent good system (RGS) value for each of a plurality of radio access technologies (RAT);
Means for associating the obtained RGS value with each of the plurality of RATs;
Means for storing the obtained RGS value and the association of the obtained RGS value.

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