DE102009052081B4 - Method for determining at least one component-specific time from a reference time in a component of a test system and corresponding communication device - Google Patents

Abstract

Method for determining at least one component-specific time from a reference time in a communication device (1), comprising the following steps: - generating and outputting (14) the reference time, - receiving (15) the output reference time by a first Component (5, 8), - determining (16) a first component-specific time on the basis of the output reference time and a first mapping rule between reference times and component-specific times using the first test component (5, 9), taking into account a first component-specific time grid, and characterized in that the method further comprises the following steps: - receiving (17) the output reference time by a second component (6, 11), - determining (18) a second component-specific time on the basis of the output reference time and a second mapping rule between reference times and k, which takes into account a second component-specific time grid component-specific times by the second component (6, 12), and that the first component (5) is designed for communication with a first communication protocol and the second component (6) for communication with a second communication protocol, the first communication protocol being the first component-specific time grid and the second communication protocol uses the second component-specific time frame, and that the first communication protocol and the second communication protocol and / or the first time frame and the second time frame are each different.

Description

The invention relates to a method for determining at least one network component-specific time from a reference time in a test system and a corresponding communication device.

From the U.S. 5,872,820 A a method is known in which a reference time in the form of a frame number is output by a mobile radio network and received by a mobile radio device. The mobile radio device determines a delay time (time lag) on the basis of the reference time (FN2) received. On the basis of the delay time, the mobile radio device determines a mobile radio device-specific time (step 555) in the form of a frame number. With the method shown, however, the reference time is output from a network component (base station sub-system) to a device that is not a network component. The method shown is used to synchronize the network component (base station sub-system) and the device, which is not a network component but communicates with the network, both using the same time grid.

DE 697 11 806 T2 discloses a communication method and apparatus for accurately dating an event. A system comprises a communication center with first communication means for the transmission of information blocks with time information, at least one communication network connected to the first communication means of the control center, at least one station with local timekeeping means and second communication means connected to the communication network and to said local timekeeping means for the transmission of information blocks with event information and time information, a clock connected to the first communication means of the control center and delivering a time information signal, as well as information processing means connected to the control center. The control center has first means connected to the time clock and the transmission means of the first communication means of the control center for determining delays resulting from the processing of first information blocks with first time information in the first communication means of the control center, as well as to the first determination means and first correction means connected to the information processing means Correction of the second time information contained in the second information blocks. The system is characterized in that said first time information is synchronization time information. Furthermore, said first delay determining means serve to determine a delay value used in the control center. The said first correction means are also connected to receiving means of the first communication means and are used to correct the said second time information contained in the said second information blocks and depicting a local time of the occurrence of an event as a function of the delay value in the control center Time information is sent out by at least one station and received by the control center.

US 2006/0177026 A1 Fig. 13 shows a telephone exchange connected via a network to a communication terminal installed in a predetermined area. The telephone exchange comprises: a reference time acquisition unit for acquiring a reference time; a storage unit that stores time difference information on a time difference between a local standard time in the predetermined range and the reference time acquired by the reference time acquisition unit; a local time calculation unit that calculates a local time in the predetermined range based on the reference time obtained from the reference time acquisition unit and the time difference information stored in the storage unit; and a communication unit that transmits the local time calculated by the local time calculation unit to the communication terminal.

In test scenarios in test systems, it is desirable that, for example, several components of the system or, for example, network component emulators, which are also referred to below as network components, can each communicate with different or common devices to be tested that are not network components themselves or are generally part of the test system . Ideally, these different network components, which can use different time rasters, for example for communication in accordance with different mobile radio standards with the devices to be tested, are synchronized with or without a relative time offset. Such a synchronization of different components for a communication between at least one component and a device to be tested is not shown. In the case of different time patterns for the individual components, adequate synchronization of the components of the test system is not possible; in particular not even if the various components or network component emulators are switched on at different times. An interfering signal occurring at a certain point in time, which is to be generated by a component of the test system, would therefore be temporally uncorrelated. One component can be, for example, a mobile radio tester that communicates with a GSM DUT (device under test; device to be tested). At some point this should Connection through a UMTS signal generated by another component can be disrupted. GSM and UMTS use different internal time frames.

One object of the invention is therefore to provide a method for a communication device - preferably a test network or test system with one or more components that can establish communication with an external device individually or together with or without communication between them - with at least one component - preferably a network component of the test network or test system - to provide with a specific time grid through which an external device to be tested can be tested efficiently and reliably by means of the component, which can be active at different times during a test procedure, for example.

The object is achieved by the method according to claim 1 and the communication device according to the independent device claim.

To carry out the method according to the invention for determining at least one component-specific time from a reference time in a communication device, a communication device according to the invention - preferably a test network or a test system of the type described above for communication with a test object or DUT - is used to determine at least one component-specific Time from a reference time used. An output unit is provided in the communication device for outputting the reference time. To receive the output reference time, a first receiving unit is formed in the communication device in a first component - preferably a first test network component for communication with the test item or DUT. To determine a first component-specific time of the first component on the basis of the output reference time and a first mapping rule between the reference time and component-specific time that takes into account a first component-specific time grid, the first component comprises a first determination unit. The communication device according to the invention further comprises a second component with a second receiving unit, which is designed to receive the output reference time, and a second determination unit, which is used to determine a second component-specific time on the basis of the output reference time and a second network component-specific time Time raster taking into account second mapping rule is formed between reference times and component-specific times. The first component is designed for communication with a first communication protocol and the second component for communication with a second communication protocol. According to the invention, the first communication protocol and the second communication protocol and / or the first time grid and the second time grid are each different.

The reference time gives the first and second components a time base on the basis of which they can set themselves autonomously - e.g. to a test procedure.

In addition to the first component, the communication device according to the invention also has the second component corresponding to the first component for communication with the or another test object or DUT, and is preferably a second test network component for communication in order to receive the output reference time in the second component with the or another test item or DUT - formed with the second receiving unit. The second component can also be provided for generating an interfering signal with regard to the communication taking place between the first component and the DUT. To determine the second component-specific time of the second component on the basis of the output reference time and the second mapping rule between the reference time and the component-specific time of the second component, which takes into account the second component-specific time pattern, the second determination unit is formed in the second component.

Due to the common reference time, both components then have a common time base on the basis of which they can be coordinated with one another - without having to communicate with one another. By individually determining their own component-specific times in relation to the units of their own time grid from the common reference time, the components can easily carry out their own action plans in their own time grid and time units independently of one another. Using the method according to the invention and the communication device according to the invention, thanks to the common reference time and the component-specific mapping functions, component-specific applications can be coordinated with one another in terms of time in such a way that, for example, particularly efficient and reliable testing of devices to be tested is possible. The component-specific presettable offsets introduced below further support such a procedure, in particular also in the case of component-specific time grids. Thanks to the method according to the invention and the test network according to the invention, it is also irrelevant when a component is switched on, for example during a test becomes; a suitable component-specific time is always determined. Thanks to the method according to the invention and the communication device according to the invention, the switched-on component and its dynamics can always be correctly embedded in the time sequence, for example of test procedures. Instead of test procedures, other processes with the respective involvement of the components can also be optimized by one of the above appropriate synchronization.

Advantageous developments of the method according to the invention and the test network according to the invention are set out in the subclaims.

The first mapping rule preferably takes into account a first component-specific offset and / or the second mapping rule takes into account a second component-specific offset. For this purpose, a first component-specific offset is preferably taken into account by the first determination unit and / or a second component-specific offset is taken into account by the second determination unit. By means of a component-specific offset, a specific time offset between a reference time and a component-specific time can be specifically determined. Such a time offset can be helpful, for example, in applications in which different time schedules for different components with different time grids have to be coordinated with one another. In this way, different time schedules can be made to run sequentially or in parallel or with a time offset in between. This means that many different test scenarios can be implemented with different systems.

The first component-specific offset and / or the second component-specific offset is preferably preset. For this purpose, the first component-specific offset in the first determination unit and / or the second component-specific offset in the second determination unit can each be stored and preset. The corresponding offsets can be adapted to specific test procedures to be implemented by presetting.

The reference time is preferably resolved more finely than the first component-specific time and the second component-specific time.

In a preferred exemplary embodiment, the first component-specific time and the second component-specific time differ. For this purpose, the first component-specific time can preferably be determined by the first determination unit and the second component-specific time by the second determination unit as different times. In this way, individual events of different time schedules of different components can be made to overlap in time or, depending on requirements, to differ in time instead. The schedules define which event of a component should occur at which point in the reference time.

• 1 eine schematische Darstellung einer erfindungsgemäßen Kommunikationseinrichtung; und
• 2 ein Flussdiagramm eines erfindungsgemäßen Verfahrens.

A preferred embodiment of the invention is explained in more detail with reference to the drawing in the following description. Show it:

• 1 a schematic representation of a communication device according to the invention; and
• 2 a flow chart of a method according to the invention.

1 shows a communication device according to the invention, which is exemplified as a test network 1 is designed to determine component-specific times from a reference time. The test network according to the invention 1 is designed such that it can be connected to an external device under test 7th which is not a component of the communication device and is in a test environment 2 is located, can communicate unidirectionally or bidirectionally.

The test network 1 comprises an output unit 3 , which is designed to output the reference time. To determine the reference time, the output unit includes 3 a reference clock 4th . The reference clock 4th has a reference time resolution corresponding to a reference time grid.

The test network 1 further comprises a first test network component 5 as the first component 5 to test the device under test 7th and a second test network component 6th as a second component 6th to test the device under test 7th . For testing the device under test 7th can be the first and / or the second component 5 , 6th be used. The first test network component 5 is, for example, a GSM protocol tester whose time grid results from the protocol scheme. The device under test 7th communicates with the protocol tester and is a GSM mobile radio device. The second test network component 6th is for example a UMTS base station emulator. The first test network component 5 and the second test network component 6th are separate devices in one embodiment, but in a common test device in another embodiment 56 integrated as units. The mobile radio standards used for explanation serve only as an example and do not limit the invention. Other communication standards or protocols can also form the basis for the different time grids.

The network components 5 , 6th of the test network 1 (the communication device) are used to set up the test network 1 (the communication facility). The device under test 7th in the variable environment 2 However, it is not a network component, ie not a component of the communication device, since it is not used to set up the test network (the communication device).

The first test network component 5 comprises a first receiving unit 8th , which is designed to receive the output reference time, and a first determination unit 9 which is designed to determine a first network component-specific time on the basis of the output reference time and a first mapping rule between reference times and network component-specific times that takes into account a first network component-specific time grid. The first mapping rule is in a first memory 10 , which is also in the first test network component 5 is included, stored. The first store 10 is in the illustrated embodiment as part of the first determination unit 9 educated. The first mapping rule can take into account a first network component-specific offset, which is also in the first memory 10 is stored. The first network component-specific offset is in the first determination unit 9 or in the first memory 10 each can be saved and preset; for example by an application and / or a user who is the first test network component 5 served. The default setting for the offset can be, for example, "0" or "no offset". The mapping rule is then used to determine how many time units have elapsed from a start time to the transmitted reference time. In the example of a GSM component, the time units result from the time slot length. It is thus determined how many timeslot (slot) of how many frames (TDMA frames) is present at the reference time.

The second test network component comprises accordingly 6th a second receiving unit 11 , which is designed to receive the output reference time, and a second determination unit 12 which is designed to determine a second network component-specific time on the basis of the output reference time and a second mapping rule between the reference time and network component-specific times that takes into account a second network component-specific time grid.

In the example of UMTS signals, their temporal structure is used here. In the second test network component 6th is also a second memory 13th formed, in which the second mapping rule is stored. The second store 13th is in the illustrated embodiment as part of the second determination unit 12 educated. The second mapping rule can take into account a second network component-specific offset. This in turn is in the second memory 13th saved. Analogously to the first network component-specific offset, the second network component-specific offset is in the second determination unit 12 or in the second memory 13th in each case - for example by an application and / or a user who is the second test network component 6th uses - can be saved and preset.

The first investigative unit 9 includes a first clock 9.4 , which specifies a first time frame with a first time resolution (in the case of GSM a time slot), while the second determination unit 12 a second clock 12.4 comprises, which specifies a second time grid with a second time resolution. The first network component-specific time can be resolved in accordance with the first time resolution using the first time grid and the first time resolution. Correspondingly, the second network component-specific time can be resolved in accordance with the second time resolution through the second time grid and the second time resolution. The reference clock 4th with the reference time resolution and the reference time grid, however, preferably provides a finer time resolution than the first time resolution and the second time resolution. To use the finer reference time resolution, there are in the first determination unit 9 the reference time finer than the first network component-specific time and in the second determination unit 12 the reference time can be resolved more finely than the second network component-specific time.

The first network component-specific time is determined by the first determination unit 9 determinable. The second network component-specific time, however, is determined by the second determination unit 12 determinable. The first network component-specific time and the second network component-specific time can each be determined as different times. In this way, each network component determines its own network component-specific time in accordance with its own mapping rule between reference times and network component-specific times and in accordance with its own time grid specified by the respective communication standard. This means that each network component can carry out its own schedule at the correct common time on the basis of its own time grid with its own time resolution. The correct time is given by the output unit 3 taking into account the reference clock 4th specified directly as a reference time or indirectly using the reference time to be processed. For each component, a schedule can be defined in the common reference time. These schedules can be sent to the individual components. The events defined in the schedule are processed there at the corresponding point in time of the network component-specific time.

Individual activities in the various schedules of the various network components are thus reliably carried out at the correct common point in time, which can be specified by a reference schedule for controlling tests.

2 shows a flowchart of the method according to the invention for determining network component-specific times from a common reference time in a test network according to the invention 1 .

In a first main step 14th becomes the reference time through the output unit 3 issued.

In a second main step 15th becomes the reference time by the first test network component 5 , or more precisely by the first receiving unit 8th received.

In a third main step 16 the first network component-specific time on the basis of the output reference time and a first mapping rule that takes into account a first network component-specific time grid between reference times and network component-specific times by the first test network component 5 or more precisely by the first determination unit 9 determined.

In a fourth main step 17th the reference time output by the second receiving unit 11 and thus by the second test network component 6th receive.

In a fifth main step 18th a second network component-specific time on the basis of the output reference time and a second mapping rule between reference times and network component-specific times that takes into account a second network component-specific time grid is determined by the second determination unit 12 and thus by the second test network component 6th determined.

The second major step 15th and the third main step 16 follow one another in a first main step sequence during the fourth main step 17th and the fifth main step 18th follow one another in a second main sequence of steps. The first main sequence of steps and the second main sequence of steps can take place next to one another or one after the other.

In some exemplary embodiments, the first network component-specific time and the second network component-specific time are the same; in other exemplary embodiments, however, they can differ from one another statistically or systematically, e.g. according to the specifications of an application.

The first mapping rule, which is the third main step 16 is used, takes into account a first network component-specific offset, which can be used to specify a start time other than "0" or "no offset" for this component. The second mapping rule in the fifth main step 18th however, a second network component-specific offset may be taken into account in the same way. The first network component-specific offset and the second network component-specific offset are the same or different, depending on the exemplary embodiment, and as such - like the first mapping rule and the second mapping rule - in the first memory 10 or the second memory 13th preset and saved. The pre-setting and saving are done before the third main step 16 or before the fifth main step 18th performed. The selection of the offsets is preferably made by an application and / or a user for a specific test procedure.

In the method according to the invention, the reference time is resolved more finely or at least not more roughly than the first network component-specific time and the second network component-specific time. However, it can also be resolved to be more coarse than one or both of the network component-specific times.

The invention is not limited to the illustrated embodiments; in particular not on communication based on mobile radio standards; in particular not on test procedures; especially not to processes that require a device outside the communication facility. Rather, individual features of the exemplary embodiments can also be advantageously combined with one another.

Claims (8)

Method for determining at least one component-specific time from a reference time in a communication device (1), comprising the following steps: - generating and outputting (14) the reference time, - receiving (15) the output reference time by a first Component (5, 8), - Determination (16) of a first component-specific time on the basis of the output reference time and a first mapping rule between reference times and, which takes into account a first component-specific time grid component-specific times by the first test component (5, 9), and characterized in that the method further comprises the following steps: - receiving (17) the output reference time by a second component (6, 11), - determining (18) a second component-specific time based on the output reference time and a second component-specific time grid taking into account a second mapping rule between reference times and component-specific times by the second component (6, 12), and that the first component (5) for communication with a first Communication protocol and the second component (6) are designed for communication with a second communication protocol, the first communication protocol using the first component-specific time frame and the second communication protocol using the second component-specific time frame, and that the first communication protocol and the second communic ationsprotokoll and / or the first time grid and the second time grid are each different. Procedure according to Claim 1 , characterized in that the first mapping rule takes into account a first component-specific offset and / or the second mapping rule takes into account a second component-specific offset. Procedure according to Claim 2 , characterized in that the first component-specific offset and / or the second component-specific offset is preset. Method according to one of the Claims 1 to 3 , characterized in that the first component-specific time and the second component-specific time are different. Communication device (1) for determining at least one component-specific time from a reference time, comprising the following devices: - an output unit (3) which is designed to output (14) the reference time, - a first component (5) with - a first receiving unit (8) which is designed to receive (15) the output reference time, - a first determination unit (9) which is used to determine (16) a first component-specific time on the basis of the output reference time and a The first mapping rule taking into account the first component-specific time grid is formed between reference times and component-specific times, and characterized in that the communication device (1) further comprises the following devices: - a second component (6) with - a second receiving unit (11) which is used for receiving (17) of the output reference time is formed, and - a second determination unit (12), which is designed to determine (18) a second component-specific time on the basis of the output reference time and a second mapping rule between reference times and component-specific times, taking into account a second network component-specific time grid, and that the first component (5) for communication with a first communication protocol and the second component (6) for communication with a second communication protocol are designed so that the first communication protocol and the second communication protocol and / or the first time grid and the second time grid are each different. Communication device according to Claim 5 , characterized in that the first determination unit (5, 9) takes into account a first component-specific offset and / or the second determination unit (6, 12) takes into account a second component-specific offset. Communication device according to Claim 6 , characterized in that the first component-specific offset in the first determination unit (5, 9) and / or the second component-specific offset in the second determination unit (6, 12) can each be stored and preset. Communication device according to one of the Claims 5 to 7th , characterized in that the first component-specific time can be determined by the first determination unit (5) and the second component-specific time by the second determination unit (6) as different times.

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