FR2984676A1 - Method for producing information associated with execution of application in e.g. portable terminal, involves producing information depending on measures performed in conjunction with current state of wireless local area network - Google Patents

Abstract

The method involves producing information depending on measures performed in conjunction with the current state of a wireless local area network (WLAN) currently used by a portable terminal. The information is produced by taking into account the type of communication in the current WLAN, the value of radio signal measured in the WLAN, the value of latency measured in the current WLAN, and the type of portable terminal, where the produced information indicates that an application is provided with degraded performance. Independent claims are also included for the following: (1) a portable apparatus (2) a computer program product for producing information associated with the execution of an application with respect to a common network currently used by a portable terminal.

Description

Method for producing information related to an application executable on a portable terminal, portable apparatus for implementing the method and associated computer program. FIELD OF THE INVENTION The invention relates to a method for providing information on the possibility of executing an application or delivering a use on a portable device. The application or the use is available using a pair consisting of a network and a device that is not necessarily the current network and device pair. 2. Prior art Nowadays, many portable devices allow us to communicate at any time and in any place, with other people or remote servers. These portable devices that are mobile phones, PADs, laptops, or smartphones (or "Smartphone" in English), use radio frequencies compatible with wireless communication networks to communicate remotely. Using these devices, a user is able to establish links with any server, via networks such as the Internet. A smartphone usually has a large screen that can display menus that allow a user to interact with it. Recent models of smartphones are equipped with a touch screen, which allows to overcome a keypad and thus increase the size of the screen. The menus displayed are controlled by resident programs in the smartphone, such as settings menus, device usage such as a photo lens or microphone, record management, and so on. Menus displayed may also come from applications received from the wireless network and saved in the smartphone. These applications use wireless networks to communicate with a specific server or not, download information and display it on the screen.

Since the first wireless communications, many technologies have emerged. In the field of mobile telephony, there are in particular 2G / GSM networks ("Global System Mobility technology" in English, literally translated as "mobile group system technology"), or 3G / UMTS ("Universal Mobile Telephone System technology"). In English, literally translated as "Universal Mobile System Technology"), or 4G / LTE ("Long Term Evolution Technology" in English, literally translated as "Long Term Evolution Technique"). Each of these networks has specific equipment for transmitting data that can be used by various applications. Thus, the latest technologies allow the reception of audiovisual documents with a certain level of interactivity. Receiving and running such applications is not possible using old network technologies. Wireless network constructs have set minimum communication quality levels to access a service. Quality of Service (QoS) is evaluated by the network and the mobile device. When launching an application, the mobile device verifies that the communication quality is sufficient for the application to function properly. According to a prior art well known to mobile phone users, the screen displays in the form of a graph, an indication of the level of the radio signal. If the level is low, the user can expect a service offered by his degraded phone, the communication may possibly be cut off. This indication refers to the level of the network currently used by the phone. In the case of telephones with several technologies (such as, for example, those qualified "triband" or "three bands" in French), in case of degradation of the signal transmitted by the current network, the phone can change network and thus improve the communication. Some applications are accessible only through certain networks, given the bit rate and QoS required for their execution. To launch such applications successfully, it is therefore desirable to ensure that the network ensures their smooth operation. The evaluation of the quality of a radio signal on other networks is performed when the current signal from the current network becomes weak and communication can be interrupted. The user who is well aware of wireless networks knows that, if the radio signal currently measured and displayed on the screen reaches a certain level, then services available on other networks will also be accessible. But communication techniques evolve rapidly, which requires updating this knowledge, more this type of information is not accessible by the majority of users. There is therefore a real need to provide users with a simple tool allowing him to know the applications and uses accessible in real time on his mobile device. 3. Objectives of the invention Current communication systems do not make it possible to evaluate the performance of an application in a given context. Thus, it is not possible for a user to determine whether the application he wants to launch can run correctly from his mobile device.

The present invention provides a solution that does not have the disadvantages described above, while providing the advantages listed above. 4. DESCRIPTION OF THE INVENTION According to a functional aspect, the invention relates to a method for producing information associated with the execution of an application relative to a current network currently used by a terminal, said application being able to be executed and to use said current network during its execution. The information produced is dependent on measurements made in relation to the current state of said current wireless network.

In this way, the user of the terminal can know the applications and services available on other networks, given the current state of the network. According to a particular embodiment, the production of the information takes into account one or more of the following parameters: the type of communication in a given network, the value of the radio signal measured on the current communication network, the latency value (or TTR) measured on the current communication network, the type of portable terminal producing the information. In this way, the information of the availability of a given application or use depends on the current state of the communication and / or the mobile terminal itself. According to another embodiment, the information is updated during a determined period of time. In this way, the user can be constantly informed of the availability of certain applications. According to another embodiment, the information produced indicates that the application is available with degraded performance. In this way, the user knows that if he launches this application, he will not get optimal operation.

According to another embodiment, a test step determines whether the portable terminal is connected to a network, the production step is triggered only if the terminal is connected to a network. In this way, the evaluation module of the availability of certain applications is not executed when there is no network to allow the proper execution of these applications.

According to another embodiment, a test step determines the identity of the operator with which said portable terminal is in communication, if the operator is not the operator who issued the subscription associated with the portable terminal, then the production step is not triggered. In this way, the module for evaluating the availability of certain applications is not executed when the portable terminal does not communicate with the network of its operator. According to a material aspect, the invention also relates to a portable apparatus including a wireless communication means said portable apparatus further including means for executing an application relative to a current network currently used by said apparatus, and a means production of information; said application being adapted to be executed and to use said current network during its execution; characterized in that the information produced is dependent on measurements made in relation to the current state of said current wireless network.

The invention also relates to a computer program product comprising program instructions for executing the method of producing information associated with executing an application. 5. List of Figures Other features and advantages of the invention will appear more clearly on reading the following description of a particular embodiment, given as a simple illustrative and non-limiting example, and the accompanying drawings. among which: - Figure 1 shows a wireless communication system having multiple networks according to an exemplary embodiment of the invention, - Figure 2 shows the main elements of a portable apparatus for implementing the invention according to an exemplary embodiment, - Figure 3 shows an example of a block diagram for determining the accessible uses and executable applications from a given portable device, - Figure 4 presents a flow chart of the main steps for the presentation of availability information. according to an exemplary embodiment. - Figure 5 shows the shape of a curve to determine the estimated actual flow. 6. DESCRIPTION OF AN EMBODIMENT OF THE INVENTION 6.1 GENERAL PRINCIPLE The present invention makes it possible to establish whether an executable application on a portable device equipped with a radio link can execute correctly in view of the current parameters of use. . The present invention consists in measuring the current level of the communication parameters with a certain network. Then, using a look-up table, equivalent parameters associated with other networks are established based on the measured levels. Finally, by comparing the equivalent parameters with the parameters necessary for the operation of an application, information is reproduced to indicate whether this application can work or not on this device and according to the current levels of communication. The present invention also relates to the server capable of bringing the two devices into communication, and a computer program comprising instructions designed to implement steps of the method. 6.2 Description of an embodiment Figure 1 describes the organization of several RATs ("Radio Access Technologies") occupying a given geographic area divided into cells. At a given location, the available networks are usually: a GERAN of 2G / GSM technology where the radio controller is called Base Station Controler (BSC), a UTRAN of 3G / UMTS technology where the radio controller is called a Radio Network Controller (RNC) ), and an eUTRAN (evolved UTRAN) used in 4G / LTE technology where the radio controller is an eNodeB. At any time, a portable device (or "ME" for short, for "Mobil Equipment") is in communication with a fixed station depending on the technology used (BSC, RNC, eNodeB). A cell is said to be close to that communicating with the ME when this cell has a coverage area covering the current position of the ME and this cell emits with a different technology, ie, another RAT. Figure 1 shows by arrow the change of RAT of an ME. The arrow represents, according to one example, the transition from UMTS technology to that of GSM. The common node with which the mobile device is in communication is, in 2G / GSM technology, a Base Station Controller (BSC). In 3G / UMTS technology, it is a Radio Network Controller (RNC). And it's an eNodeB in 4G / LTE technology. The right part of Figure 1 represents the heart of the network (or "CN" abbreviated for "Core Network"). CN sees all exchanges of information between RNCs, BSCs and eNodeBs, CN ensures the continuity of a communication when the mobile decides to change RAT. FIG. 2 illustrates the main elements of a portable device according to an exemplary embodiment, said portable device being a mobile phone, a PDA, a laptop, a smartphone, or any portable device having a wireless link for communication . The portable device 1 comprises an ALU 1.1 central unit connected to an executable program memory MP 1.2, a screen S 1.3, a radio communication module 1.4, and an interface module 1.5 with a keyboard 1.6. The communication module allows communication in the radio frequency range compatible with wireless communication networks such as: 2G / GSM, 3G / UMTS or 4G / LTE. Each of these three networks has several types of communication (or "bearer" in English). Flow and latency characteristics are standardized for each type and network. The screen 1.3 can be touch, the keyboard 1.6. is then integrated in this screen. The program memory contains resident executable programs and optionally a part of type Read / Write for recording and executing downloaded programs. These downloaded programs are typically applications dedicated to a specific use such as messaging, searching information on the Internet, downloading audio and / or visual documents, teleshopping, etc. The program memory MP contains an evaluation module Application Operation, or EFA module for short. This module is responsible for evaluating the execution possibilities of at least one application taking into account the current measurement of the radio parameters, and displaying the possibilities to inform the user. After having detailed the various elements of the invention, we will now explain how these cooperate. Figure 3 presents a block diagram for the determination of accessible uses and executable applications from a given portable device and in a radio context. given. This determination takes into account the following parameters: - the networks (the performances of each network), - the type of portable device, - the type of communication (the "bearer") - the level and / or the quality of the radio signal - the measurement of the TTR ("Time To Response"), optionally.

Figure 4 shows the main steps performed by the executable module of the portable device when evaluating the application operation.

In a first step (step 4.1), the portable device 1 enters into communication with a wireless network. This technology is well known and does not require additional information. The communication module 1.4 supplies the EFA module with the current value of radio parameters characterizing the current communication, such as: - type of communication (or "bearer" in English), - signal amplitude, - signal quality. In a second step (step 4.2), the EFA module determines the value of a parameter representative of the current signal and the current state of the portable device and which will make it possible to evaluate the access to certain uses and applications. This parameter is the estimated actual flow. The actual rate takes into account several types of data: I) The static configuration data on the basis of which the system is parameterized, for example: - the type of terminal, - the performance of networks (including 2G & 3G networks), - categorization of uses and associated requirements. II) Non intrusive and intrusive dynamic measurements made from the terminal, for example: - Strength / quality of the radio signal and active bearer, - TTR (Time To Response), III) The quantities (intermediate or final) calculated, for example: The typical theoretical flow rates by bearer. Some of these parameters are given by way of example and have an optional character within the scope of the invention. The table below shows the performance achieved in a 2G network. This table provides in particular the minimum and maximum values of upstream (UP) and downstream (DOWN) for the application to function properly. Downflow Type Upstream Flux Technology Bearer Generation - Bearer Flow - Throughput Type (kb / s) Type (kb / s) Technology Technology 2G TD1VIA 2.5G GPRS 48 GPRS - 2.75G EDGE 171 EDGE - The table below below shows the performance achieved in a 3G network. 20 Type of Generation Downstream Technology Bearer - Type Version HSDPA Category HSDPA Rate (kh / s) Technology UMTS or 3G HSUPA - - 384 6 3600 HSDPA or 8 7200 HSPA 9 10100 3G 14400 CDMA 3G + 14 21100 7 16 28800 HSPA + 20 42200 8 22 28800 24 42200 Generating Network Flows up n Bearer - Type of technology Version Category HSUPA HSUPA bit rate (kb / s) UMTS or 3G HSDPA - - 128 1 730 2 1460 3G HSUPA or 3 1460 CDMA 6 3G + HSPA 4 2000 5 2920 6 5760 HSPA + 7 7 11500 The table above shows the parameters of the various communication types such as: 2G / GSM, 2G / GPRS, 2G / EDGE, 3G / UMTS, 3G + / HSDPA, In a third step (step 4.3), the EFA selects an application or a usage to evaluate. The module EFA manages in the memory 1.2 of M.E. 1 a table containing the following information: - identifier of use or application, - minimum flow, - maximum flow, - latency. The selection of the application or the use can be made by a user action on the keyboard 1.6 of the ME. The selection can also be done automatically, for example at a specific time of the day an application must be triggered, the ME checks whether this execution is possible and if not, warns the user of the probable impossibility of the application. execute. An example of a table listing the typical applications or uses that are available on a bortable terminal is given below: Minimum requirements Usage or application identifier Flow down Flow down Typical minimum latency Surf the Internet 100 KB / s 400 Kb / s X ms Watching TV (streaming video) 400 kb / s 600 kb / s Y ms Other applications or uses can be identified by this table. These include: - communicating (messaging without attachments, social networks), - calling (voice over IP), - playing a network, - listening to music (streaming audio), - synchronizing my data. Once a usage or an application is selected, the EFA module derives from the table above the parameters to provide the use or to operate the selected application. According to a particular embodiment, the EFA module uses a formula to establish the weighting according to the received signal. This graph is for example that of a hyperbolic tangent. Figure 5 shows the shape of a curve to determine the estimated actual flow. This curve is typically divided into three continuous zones: a first plateau zone for which the measured signal strength is sufficient to obtain a (quasi) nominal flow rate; a last plateau zone for which the measured signal strength is insufficient for obtain a significant flow, - an intermediate transition zone and width given within which the nominal flow changes almost linearly depending on the measured signal strength.

Advantageously, the apparatus 1 stores the formula and not the points of the curve, here is an example of the formula: D '= (th ((SR - (SRmax + Offset) I 2) / slope) + 1) / 2 * / _) 'Where th denotes the mathematical function "hyperbolic tangent". The formula contains the following parameters: D, is the estimated actual estimated flow rate Dtt is the typical theoretical flow of a given bearer SR designates the received signal indicator calibrated according to TS 27.007 8.5 and can take values from 1 to SRmax - SR. designates the maximum received signal indicator (here 31) - Offset: allows the centering of the transition zone; the value "1" corresponds to a centering of the transition zone for a value of RSSI = 16 - Slope: allows the adjustment of the progressivity of the transition zone. The value "1" makes it possible to obtain a transition zone of minimum size. In a fourth step (step 4.4), the EFA module correlates the measured parameters of communication or calculated (including the estimated actual flow), with the parameters necessary for the use or application requested is available. Typically, for the use or application to be available, the required parameters must be in the range indicated by the table. According to a particular embodiment, the table provides other information specifying the threshold beyond which the use and the application is available but in degraded mode. The programmatic interface then provides three indications: the use / application is not available, the use / application is available but in degraded mode, the use / application is available at 100%. In a fifth step (step 4.5), the EFA module displays the results of the evaluation. If the module is called to evaluate the availability of a use or an application, then the message displayed concerns only this use or this application. In another embodiment, the EFA module evaluates the availability of a list of use and application. In this case, the EFA module displays the results as a table. According to a first embodiment, the displayed results are presented in the form of an expression that can take three different values: "Available", "Available degraded mode", "Not available". According to another embodiment, the results appear in the form of icons, or else by a color code: the green color means that the use or the application is "Available", the orange color means that the use or the application is "Available degraded mode", and the red color means: "Not available".

According to a particular embodiment, the evaluation by the EFA module takes into account the value of the TTR ("Time To Response"). The taking into account of this parameter can be at the explicit initiative of the user. It can also be taken into account unitarily, at the time of the evaluation, not to unnecessarily load the network by unnecessary PING requests at the present time. This parameter complements flow estimates by an effective measurement of the response time. This parameter can be particularly important for certain applications such as VoIP or online games where the response time of the interlocutor is important.

According to a particular embodiment, the menu displaying the availability of uses or application is updated during a specified period of time, typically every second. According to a particular embodiment, the user can enter the period value for updating the evaluation. According to an alternative embodiment, the displayed menu includes an update icon or submenu that the user can activate. According to a particular embodiment, the EFA module tests at its launch if the ME is connected by radio to the network. If this is not the case, the module can not evaluate the availability of any use or application, and inform the user by a specific message. According to a particular embodiment, the EFA module is not activated when the operator of the current network is not the operator having delivered the subscription associated with the portable device. The invention is not limited to the embodiments that have just been described. In particular, the invention can be implemented by any portable device having a user interface and a wireless communication means.

Claims (8)

REVENDICATIONS1. A method of producing information associated with the execution of an application relative to a current network currently used by a terminal, said application being adapted to be executed and to use said current network during its execution; characterized in that the information produced is dependent on measurements made in relation to the current state of said current wireless network. 2. Method according to claim 1, characterized in that the step of producing the information takes into account the type of communication in a given network. 3. Method according to claim 1 or 2, characterized in that the step of producing the information takes into account the value of the radio signal measured on the current communication network. 4. Method according to claim 1 or 2, characterized in that the step of producing the information takes into account the latency value measured on the current communication network. 5. Method according to claim 1 or 2, characterized in that the step of producing the information takes into account the type of portable terminal 25 producing the information. 6. The method of claim 1; characterized in that the information produced indicates that the application is available with degraded performance. 30 7. Portable apparatus (1) including a wireless communication means (1.4) said portable apparatus further including means (1.1, 1.2) for executing an application relative to a current network currently used by said apparatus (1) , and means for producing (1.3) information; said application being adapted to be executed and to use said current network during its execution; characterized in that the information produced is dependent on measurements made in relation to the current state of said current wireless network. 8. Computer program product downloadable from a communications network and / or stored on a computer readable medium and / or executable by a central unit, characterized in that it comprises program instructions for the implementation of at least one step of the method of producing information according to any one of claims 1 to 6.