DE102010007293A1 - Audio and/or vibration test carrying out device e.g. antenna coupler, for mobile telephone, has sound receiver receiving signal delivered via speaker of telephone over impact sound produced by signal during audio and/or vibration test - Google Patents

Abstract

The device i.e. antenna coupler (1), has a sound receiver i.e. piezoelectric or piezoceramic element (18), receiving a signal delivered via a speaker of a mobile telephone over impact sound produced by the signal during an audio and/or vibration test at the mobile telephone. The signal is selected from one of an audio signal such as audio test signal, call signal and bell sound, and a signal produced by vibration of the mobile telephone. The receiver is attached within a housing (2) of the device. The audio test signal is provided as a monofrequent audio signal with predetermined frequency. An independent claim is also included for a method for carrying out of audio and/or vibration tests at a mobile telephone.

Description

The present invention relates to a device for performing an audio and / or vibration test on a mobile telephone. Furthermore, the present invention relates to a method for performing an audio and / or vibration test on a mobile telephone. Finally, the present invention relates to a use of a sound pickup for performing an audio and / or vibration test on a mobile phone.

In the prior art radio testers or devices for testing mobile phones are known. Such a radio test station generates a test network, in which a test mobile phone, which is equipped with a special test SIM card (SIM = Subscriber Identity Module), can register for test purposes. The test network is operated according to a mobile radio standard, e.g. As the UMTS standard operated. The testing of mobile phones is thus carried out so to speak, very realistic, as well as in operation, the mobile phones in an existing mobile network log and exchange data with this. To carry out the test, a connection is now established between the radio tester and the mobile telephone, this being done either by a call from the radio tester at the mobile telephone or vice versa by a call from the mobile telephone to the radio tester. Following this, certain test procedures or routines are carried out, in particular, to check the transmission and reception capability of the mobile phone with regard to compliance with the specifications required for proper operability, which are specified by the manufacturer. For example, this data is transmitted from the radio tester to the mobile phone and then transmitted back from the mobile phone to the radio tester, these data are then checked for authenticity. As a result, moreover, measurement results of various parameters are displayed in a measurement log which can be displayed, stored and / or printed out. In particular, the overall result of the test, namely "passed test" or "failed test", is also supplied. Such radio testers for testing mobile phones find in practice a variety of applications. These are for example in the manufacture of mobile phones, z. For example, in the final inspection or in an intermediate step of the production in a factory in which mobile phones are manufactured used. Such an intermediate step serves, for example, for balancing components. Every mobile phone produced should be tested prior to shipment, making this final test a bottleneck for the entire manufacturing process, due to the time required to do so. Namely, the mobile phones are tested individually and successively at a measuring station. Another application of such radio measuring stations is their use in so-called service centers to which defective or supposedly defective mobile phones are sent for repair. Here it is important to first determine whether the mobile phones are actually defective, and to analyze whether and how, for example, by replacing a particular component, they can be repaired. In such service centers, a variety of mobile phones of different types and from different manufacturers is often tested, on the one hand, if they go to the service center, and on the other hand, even after repair. Finally, such radio measuring stations are also used in the development of mobile phones from manufacturers.

In principle, the radio connection between the radio tester and the mobile phone can be made via corresponding RF cables. In practice, however, has prevailed to carry out the connection between the radio tester and mobile phone over the air interface, so that the radio tester is connected in the test mode with an antenna coupler having an antenna which can couple with the antenna of the mobile phone. The testing of mobile phones is thus carried out very realistic. The radio measuring station together with the antenna coupler is a small test base station, with the particular advantage that the antenna of the mobile phone and the components upstream and downstream are also tested. Examples of such antenna couplers are in the German patent DE 197 32 639 C1 as well as the German Offenlegungsschriften DE 103 56 087 A1 and DE 10 2004 033 383 A1 of the present applicant, the entire disclosure content of which is incorporated by reference into the present application.

To the RF measurement of disturbing environmental influences, eg. As from existing real mobile networks to shield, the antenna coupler and the mobile phone to be tested are used during the test in a shield. An example of such a shielding is in the German patent DE 10 2004 049 354 B4 the disclosure of which is incorporated herein by reference in its entirety.

A part of the test of mobile phones is the so-called audio test, in which the microphone and the speaker of the mobile phone and connected components are tested. Currently, such an audio test is performed in the form of an echo test or a "manual" loopback test. As part of the test, which lasts for about half a minute, the service person or operator is asked to open the shield case and say "hello" into the microphone of the mobile phone, for example. The recorded via the microphone signal is transmitted from the mobile phone via the antenna coupler to the radio tester, and then transferred back to the mobile phone or looped back and output via the speaker of the mobile phone. If the operator considers the retransmitted and then output echo signal to be satisfactory, the test is passed.

This method has a number of disadvantages. First, the test of the acoustic properties of the mobile phone takes a relatively long time compared to the total test duration. In addition, the audio test is not automated, but it is the use of an operator required, which is then blocked for other work. Since an operator usually works at several test sites at the same time and inserts the mobile phones there and removes them again after the test has been completed, carrying out an audio test for the test personnel is very time-consuming. The test result is also not particularly objective, since the subjective perception of the operator, who is exposed to a variety of disturbances and usually performs further work in parallel, decides on the test result. Finally, it is also problematic that in such test environments often a disturbing noise level is present, so that the testing by an operator at. opened shielding is difficult because this ambient noise is also recorded by the microphone of the mobile phone.

The invention is therefore based on the object automatically perform an audio and / or vibration test for a mobile phone to minimize the personnel required for the test and to obtain objective test or measurement results.

In a device of the type mentioned above, this object is achieved by a sound pickup, which receives a signal emitted by the mobile phone during the test on the structure-borne sound generated by the signal.

An advantage of the present invention is that the automation of an audio and / or vibration test in the construction achieved by the invention is simple and inexpensive in practice.

Another advantage of the present invention is that HF measurements of the transmission and reception characteristics of the mobile phone are impaired or falsified as little as possible, and the testing or measuring of the audio properties by the RF measurements or the operation of the mobile telephone is not affected.

The Applicant of the present application has made a variety of attempts to automate an audio test for a mobile phone. There was a first approach to the automation of an audio test in the arrangement of a speaker and a microphone within the shield. While a loudspeaker in the shield case is relatively unproblematic, the use of a microphone within the shield case presents great problems. The arrangement of a microphone, which in particular also has to be aligned with the loudspeaker of the mobile phone to be tested, for example by means of a goose neck mount in order to adjust to the different positions of mobile phone loudspeakers, is extremely problematic in the high-frequency field in the interior of the shielding housing. Bursts (frequency at about 200 Hz) act on the existing in the middle of the shield housing supply cable of such a microphone and on the microphone itself. Since the speaker of a mobile phone is almost always located in the immediate vicinity of the antenna of the mobile phone, there are great problems in this regard. However, it is particularly serious that the coupling factor between the antenna coupler and the mobile phone to be tested greatly changes in the presence of the microphone. The coupling factor must be known before starting the measurement, since the measurement results are meaningful only if the coupling factor is known. In particular, this also occurs the problem of reproducibility, which inevitably occur at a respective readjustment of a microphone holder. The inventive measurement of structure-borne noise by a corresponding structure-borne sound sensor overcome these problems.

In a preferred embodiment of the invention, the sound pickup is a piezoelectric or piezoceramic element. Due to the piezoelectric or piezoceramic component, the airborne sound is not recorded as in a microphone, but instead the structure-borne sound. The structure-borne sound spreads, for example, from the speaker of the mobile phone through the case of the mobile phone through all physically related components and therefore can also be removed remotely from the mobile phone, and in particular at a location that does not interfere with the primarily relevant RF measurement. The sound pickup is therefore designed as a structure-borne sound microphone, and is preferably a piezoelectric element.

It is further preferred that the test is an audio test and that the signal is an audio signal which is output via the loudspeaker of the mobile telephone. The audio signal may be, for example, an audio test signal in the form of a sine wave. It is also preferred that the audio signal is a conversation signal, for example a spoken text. The ringing tone, which signals that the mobile phone is being called, can also represent such a signal.

It is also preferable that the test is a vibration test, and that the signal is generated by a vibration of the cellular phone. In particular, it has been found through experimentation that vibration of the mobile telephone, for example when the vibration is set as call signaling or vibration alert, can be detected by a piezoelectric or piezoceramic device, since such vibration generates structure-borne noise which is in the range of the resonance frequency the piezoelectric or piezoceramic component is located.

Preferably, the sound sensor is arranged on the mobile telephone or on a directly or indirectly connected to this part of the device. The structure-borne noise signal picked up by the transducer is always strongest directly on the mobile phone. However, an attachment of the Schallaufnehmers directly on the mobile phone is in principle not particularly practical, since there is no standardized connection option. Furthermore, the sound pickup should not be too close to the mobile phone, otherwise its operation, but also the ongoing RF measurement operation, is disturbed. Since the structure-borne noise propagates to all parts of the test device that are directly and indirectly connected to the mobile phone, the sound sensor can also be arranged remotely from the mobile phone and in particular also remote from its antenna.

Furthermore, it is preferred that the device is an antenna coupler or has an antenna coupler. In this case, the sound sensor is preferably arranged on or in one of the following components of the antenna coupler: holder for the mobile telephone, positioning slide of the holder, housing of the antenna coupler. It is particularly preferred that the sound pickup is mounted within the housing of the antenna coupler, wherein the sound sensor is disposed on a remote from the antenna of the inserted in the intended position mobile phone end of the housing, and / or that the sound pickup is mounted within the housing of the antenna coupler , wherein on one side with respect to an antenna of the antenna coupler, the mobile phone inserted in the intended installation position is arranged, and wherein the sound pickup is arranged on the side opposite to the one side with respect to the antenna. This results in a preferred arrangement of the Schallaufnehmers, as this does not affect the RF measurement, and is not affected by this.

The audio test signal can in principle be transmitted to the mobile phone in a number of ways. For example, it can be transmitted directly from the radio measuring station via the antenna coupler and the air interface to the mobile phone, where it is output from the speaker. In this case, only an audio test takes place on the loudspeaker or on these upstream components. It is therefore not mitgetestet the microphone. However, it is also possible to perform a so-called echo test, d. H. the audio test signal is transmitted to the microphone of the mobile telephone from a loudspeaker, preferably arranged in the shielding housing, and forwarded from the mobile telephone via the air interface to the antenna coupler and then to the radio tester, and then the audio test signal is looped back to the mobile telephone as described above, and with a time delay output via the speaker of the mobile phone.

Furthermore, it is preferred that the device is a shielding housing. During the test of a mobile phone it is attached to an antenna coupler and the antenna coupler is disposed in the shield case. By the device is or has a shield case, the sound pickup can still record the structure-borne sound emitted by the mobile phone audio or vibration signal, for example via a fastening or fixing device, for. B. in the form of a retaining clip with which the antenna coupler is fixed or fixed in the shield. The design of the Schallaufnehmers in the shield does not only provide a simpler retrofit option for the use of proposed by the invention novel audio and vibration test, since no new antenna coupler must be purchased, but is also preferred for metrological reasons. By doing Shielding the transducer as possible removed, but still shielded from disturbing external influences are arranged by the mobile phone. Such an arrangement disturbs the RF measurement very little or this also has low interference on the audio and / or vibration test. In particular, the leads to the sound pickup then also do not run within the measuring chamber of the shielding housing or these can be very short, since they are led out of the shielding housing. For an echo test, a loudspeaker is provided on an inner wall of the shield case, and preferably the sound receiver is also disposed adjacent to the inner wall of the shield case, so that the test equipment for the audio and / or vibration test are combined in close proximity. This also simplifies the routing of cables to the (audio and vibration) test equipment.

Preferably, the electrical sensor downstream of an electrical circuit arrangement, wherein the circuit arrangement comprises an amplifier and / or a filter. In particular, in an embodiment of the sound pickup as a piezo element this has a broad resonance. In order to filter out interfering structure-borne noise, which acts on the sound pickup, a preferably narrowband filter is preferably connected downstream of the sound pickup (compared to the width of the resonance frequency of the piezoelectric element). The filter is a bandpass filter, which is permeable in the region of the resonant frequency of the piezoelectric element, and has a filter bandwidth of preferably a few tens of hertz. Subsequent to the filtering, the structure-borne sound signal recorded by the sound pickup is amplified by the amplifier and, for example, transmitted to the radio test station.

In a method of the type mentioned above, this object is achieved in that during the test a signal emitted by the mobile phone signal is recorded by a sound pickup on the structure-borne sound generated by the signal.

Preferably, the test is an audio test and the audio test signal is a mono-frequency audio signal, e.g. B. a sine signal, with a predetermined frequency which corresponds approximately to a resonant frequency of the sound pickup. More specifically, it is preferable that the frequency of the audio test signal also falls within the range of the filter connected downstream of the sound pickup. The audio signal therefore preferably has only those frequency components which lie in the region of the resonance frequency of the sound pickup and the downstream filter. By comparing the audio test signal with the signal picked up by the sound pickup, therefore, the audio quality can basically be tested or evaluated.

Furthermore, it is preferred that a plurality of audio test signals is used for carrying out the audio test, one of the plurality of audio test signals having the predetermined frequency, and the further audio test signals having a respective frequency which is different from the predetermined frequency by dividing by a natural number n, which is greater than or equal to 2, is lowered. For performing the audio quality measurements, therefore, an audio test signal having a fundamental frequency which is close to the resonance frequency of the sound pickup is used. Since, in principle, the harmonics or harmonics of the signal output by the loudspeaker of the mobile phone must be examined for the quality measurement, this can not be done, for example, by a piezoelectric sound receiver with a downstream bandpass filter because of its narrowband or narrow passband. Therefore, it is preferable to use a test routine having a plurality of audio test signals each reduced in frequency by a natural number n (n ≥ 2). This special set of test signals ensures that the (n - 1) th harmonic falls back into the measuring range of the piezoelectric transducer. In principle, any number of such audio test signals with increasingly reduced frequency can be used to measure the harmonics up to a certain order. In practice, however, few audio test signals are sufficient for this because the amplitude of harmonics of increasing order decreases rapidly.

In order to determine a quality measure for the audio test, it is preferred that the respective signal levels output by the loudspeaker of the mobile telephone during the plurality of audio test signals are compared with respective predetermined threshold values. Preferably, the signal levels are, for example, rms values, peak levels, etc. By comparison with respective predetermined threshold values, a quality measure for the audio test can therefore be determined. If the levels of the signal output from the speaker are too large, in particular greater than the predetermined threshold values, then the test is correspondingly poor.

wobei Ū₁ der Effektivwert des Audiotestsignals mit der vorbestimmten Frequenz ist, und wobei Ū₂, Ū₃, Ū₄...Ū_N die Effektivwerte der vom Schallaufnehmer aufgenommenen Oberwellen N-ter Ordnung sind. Selbstverständlich ist es erfindungsgemäß auch möglich die Anteile einer oder mehrerer einzelner Oberschwingung, d. h. insbesondere einen Einzelklirrfaktor für eine Oberwelle, zu bestimmen und als Qualitätsmaß zu verwenden.A further preferred embodiment of the invention provides for the determination of a quality measure that a respective harmonic distortion of the loudspeaker is calculated from the respective signal levels output by the loudspeaker of the mobile telephone during the plurality of audio test signals. The harmonic distortion k indicates how strong the harmonics (harmonics), the distortion of a sinusoidal signal are formed compared to the overall signal. It is the ratio of the harmonic rms value to the total rms value, including the fundamental vibration component. For a harmonic signal, the total harmonic distortion k is determined by the formula:

where Ū _{1 is} the rms value of the audio test signal having the predetermined frequency, and where Ū ₂ , Ū ₃ , Ū ₄ ... Ū _{N are} the RMS values of the N-th order harmonics picked up by the sound pickup. Of course, it is also possible according to the invention to determine the proportions of one or more individual harmonics, ie in particular a single harmonic distortion factor for a harmonic, and to use them as a quality measure.

Further preferred embodiments of the invention are disclosed in the dependent claims.

The invention, as well as other features, objects, advantages and applications thereof, will be explained in more detail below with reference to a description of preferred embodiments with reference to the accompanying drawings. In the drawings, the same or similar reference numerals designate the same or corresponding elements. All described and / or illustrated features alone or in any meaningful combination form the subject matter of the present invention, regardless of their combination in the claims or their dependency. In the drawings show in a highly schematic representation:

1 a schematic perspective view of an antenna coupler according to an embodiment of the present invention.

2 a schematic view in longitudinal section of the antenna coupler of 1 in which one recognizes the attached thereto Schallaufnehmer;

3 a highly schematic representation of a test setup for a mobile phone according to a preferred embodiment of the present invention.

1 shows in perspective an antenna coupler 1 which serves to wirelessly connect a (not shown) mobile device (eg a mobile phone or the like) in a measuring system. The in 2 also in sectional view to be seen antenna coupler 1 provides a wireless communication to the mobile device and in turn (not shown manner) wired connected to a measuring device or radio tester.

The antenna coupler 1 has a housing 2 on top of which is a bracket 3 is formed, which is realized in the illustrated embodiment as a universal mobile device holder. It can accommodate a variety of mobile phones and also PDA mobile phone combination devices. The holder 3 is on a sledge 4 attached to a frame 5 which is the top of the case 2 forms, is guided displaceably.

To measure the mobile device is in the holder 3 inserted and at the in 1 illustrated construction with jaws 6 . 7 the holder 3 fixed. The radio communication takes place between the antenna of the mobile device and an antenna in the housing 2 below the frame 5 is attached. The antenna of the antenna coupler is formed in the embodiment described here as a planar antenna in stripline technology.

At the bottom of the holder, the mobile device is located at a stop 8th so it's on a support surface 9 from the jaws 6 . 7 and the stop 8th is held securely. Depending on the design, the mobile device is more or less on the holder 3 above. For most mobile devices, the antenna is in this protruding area.

In order to avoid disturbances of the radio communication, the carriage has 4 therefore a recess 10 so that no or as little as possible disturbing material between one over the holder 3 protruding antenna of a mobile device and the surface antenna of the antenna coupler 1 to come to rest.

The sled 4 is along the longitudinal axis of the antenna coupler 1 displaced. He has a locking mechanism 11 on that together with at the frame 5 trained grooves the sled 4 locked in different positions. At the sled 4 attached hands allow the position of the carriage 4 easy to detect when markers are attached above the surface antenna (to be described). One on the support surface 9 the holder 3 laid and by means of the jaws 6 and 7 Fixed mobile device can be placed in an optimal position to the surface antenna. To release the jaws 6 and 7 is on the bracket 3 a button provided, one in the holder 3 provided, the jaws 6 and 7 arresting locking mechanism releases.

Like the sectional view of the 2 clearly shows, is the case 2 from a bottom part 11 and the frame attached to it 5 built up. The frame 5 is about pins 12 with the bottom part 11 connected and clamped an antenna board 13 inside the case 14 fixed, on which the surface antenna is formed. To the antenna board 13 runs inside the case 14 an antenna cable via a converter 15 to a grounding board 16 , on which a coaxial input is provided.

On the basis of the location of the mobile device lower side of the antenna board 13 ie on the side of the antenna board 13 leading to the housing interior 14 is located, a two-armed spiral antenna is formed. The connections of the two arms of the spiral antenna are through the converter 15 with the bottom of the under the antenna board 13 lying grounding board 16 connected. The converter 15 directs the two connections of the spiral antenna, which are next to each other, on the coaxial input. So he is on the input side with the antenna board 13 and connected on the output side with a shield contact and a center contact of the coaxial input.

On the top of the grounding board 16 ie on the antenna board 13 facing side, a shielding surface is provided for the converter 15 is suitably structured and otherwise serves as a ground plane. On the bottom of the grounding board 16 a shielding structure is also provided as well as a corresponding connecting conductor, which is the converter 15 on the center contact of the coaxial connector sets.

The antenna board 13 lies relative to the carriage 4 with its spiral antenna structure down in the housing, forming in the area of the interior of the frame 5 the top of the case 2 , As a result, the conductor structure of the spiral antenna is protected from damage. The grounding board 16 shields the spiral antenna downwards and at the same time acts as a reflector. The distance between grounding board and spiral antenna is in the exemplary embodiment about 2.3 cm. It is typically not significantly greater than a quarter of the wavelength of the upper limit of the desired frequency band in which the antenna coupler is used. Under no circumstances should the distance be equal to half a wavelength. The bottom part 11 shields the inside of the housing and the antenna at the edge.

A piezoelectric element acting as structure-borne sound pickup 18 is on the bottom of the bottom part 11 glued. More precise is the piezo element 18 on the from the antenna of the intended position in the holder 3 inserted mobile phone remote side arranged in the bottom part. It is also below the grounding board 16 provided in order to disturb the RF measurement as little as possible due to their shielding effect. An audio signal emitted by the loudspeaker of the mobile telephone or a vibrating of the mobile telephone produces, in addition to the airborne sound, also a structure-borne noise which extends from the mobile telephone via the holder 3 , the positioning slide 4 , and the case 2 of the antenna coupler 1 spreads. Thus, the structure-borne noise is good at the bottom part 11 of the antenna coupler 1 be recorded. The piezo element 18 but it can also be found elsewhere on the antenna coupler 1 or else on an inner wall of a shielding housing (cf. 3 ) can be arranged.

Based on the highly schematic representation of 3 In the following, the test setup for testing a mobile phone is explained in further detail. In this case, in particular, an audio test is performed, ie it will be the microphone and / or the speaker of the mobile phone 20 as well as upstream and downstream components tested. The schematically indicated antenna coupler 1 has one in its holder 3 (in 3 not shown) used mobile phone 20 on. The antenna coupler 1 with inserted mobile phone is in a shield 30 arranged during the test. Through the shielding housing 30 disturbing external RF fields are shielded, so that the antenna coupler 1 as undisturbed as possible with the mobile phone 20 communicates via the air interface. More specifically, it couples to the antenna board 13 (see. 2 ) provided antenna with the antenna of the mobile phone 20 , The entire test or measurement procedure is performed by a test device for mobile phones, ie a so-called radio tester 40 , controlled. The radio tester 40 serves as a small base station, in the radio network is the mobile phone to be tested 20 via a specially inserted test SIM card. The RF test signals are transmitted via in 3 Not shown RF cables through the shield 30 to the antenna coupler 1 delivered and received by this. Since the operation of a radio measuring station is known in the prior art, it will not be discussed further in the present description.

To perform an audio test on the mobile phone 20 is in the shield case 30 a loudspeaker 31 provided, which preferably on an inner wall of the shielding 30 is arranged. The speaker 31 receives an audio test signal, which is preferably a monofrequency sine signal, from the radio tester 40 over the line 32 , At the end of the line 32 is an amplifier 33 provided, whereby the amplified signals over the lines 34 and 35 to the speaker 31 to be delivered. The trained by the present invention as a piezoelectric transducer 18 supplied signals are transmitted via the lines 21 and 22 to a narrow band filter 23 which has a bandwidth of about several tens of Hz, preferably in a range of about 20 to about 30 Hz. The filter 23 is used to filter out disturbing structure-borne noise, which has nothing to do with the audio or vibration measurement. Through the filter 23 Therefore, the signal-to-noise ratio is improved. Over the lines 24 and 25 The signals are sent to an amplifier 26 delivered by the amplifier 26 amplified signal over the line 27 to the radio tester 40 is delivered. The speaker 31 upstream electronics is in its entirety by the reference numeral 39 designated. The the piezo element 18 Downstream electronics is in their entirety by the reference numeral 29 designated. For current or voltage supply of the electrical circuit arrangements 29 respectively. 39 is a power supply 50 provided that one at its entrance 51 applied AC signal into a DC signal, and over the lines 52 and 53 to the electrical circuitry 39 respectively. 29 supplies. The better clarity, are in 3 the electrical circuit arrangement 29 and 39 shown separated from each other. In a preferred embodiment, however, the electrical circuitry 29 and 39 integrated formed, for example, on a single board, and are preferably in a housing directly outside the rear wall of the shielding 30 appropriate. In any case, it is preferred that the electrical circuits 29 and 39 outside the shielding housing 30 are arranged so as not to influence the measurement or by the RF radiation within the shielding 30 not to be impaired in their function.

As already mentioned, it is possible by the invention to automatically perform an audio test. Such an audio test preferably forms part of an entire test routine in which all parameters of the mobile phone to be tested are tested. According to the preferred embodiment, the audio test is performed as a so-called echo test or loopback test. This is one of the speakers 31 in the shield case 30 radiated audio test signal from the microphone of the mobile phone 20 received and from the mobile phone 20 via the antenna coupler 1 to the radio tester 40 transfer. After that, it will be radio-controlled 40 received audio test signals back via the antenna coupler 1 to the mobile phone 20 transmitted, and there from the speaker of the mobile phone 20 output. That from the speaker of the mobile phone 20 output audio test signal is therefore an echo of the speaker 31 delivered test signal. The piezoelectric element 18 takes that from the speaker of the cellphone 20 radiated audio signal on the structure-borne sound, and passes this filter after filtering through the filter 23 and gain through the amplifier 26 to the radio tester 40 further. In the radio tester 40 Therefore, the quality of the audio components (essentially microphone and speakers) of the mobile phone 20 be rated. Instead of the radio tester 40 For example, a personal computer may also be used to perform the audio test, with the audio test signals being output via the sound card. Also, for example, the speaker of the mobile phone 20 regardless of the microphone of the mobile phone 20 be tested by a test signal from the radio tester 40 via the antenna coupler 1 to the mobile phone 20 is transmitted, ie it finds no broadcast of a test signal through the speaker 31 instead, so that the microphone is the mobile phone 20 not used. The way to the mobile phone 20 transmitted audio test signal is there from the speaker of the mobile phone 20 output and from the piezo element 18 taken and to the radio tester 40 transfer. If the audio test signal is unadulterated in good quality at the radio tester 40 It can be concluded from this that the speaker or this upstream components of the mobile phone 20 works properly.

The piezo element 18 In particular, one can also use the speaker of the mobile phone 20 pick up the ring tone and send it to the radio tester 40 transfer. For example, you can do this by simply calling the radio tester 40 at the mobile phone 20 , wherein the occurrence of the Anruftons by the piezoelectric element 18 automatically take further action. For example, the lid of the shielding 30 be opened automatically. Likewise, the radio tester 40 a vibration of the mobile phone 20 bring about, for example in the form of a vibrating alarm or as a "ringing tone", this in turn of the piezoelectric element 18 is detected.

The piezo element 18 has a strong broad resonance frequency, z. In a range of about 2 kHz. As explained above, the piezoelectric element 18 for metrological reasons, the narrow-band filter 23 downstream, resulting in a total narrowband this Schallaufnehmer-filter system. In order to provide particularly meaningful measurements with regard to the audio quality of the mobile phone 20 is actually a broadband frequency analysis of the speaker of the mobile phone 20 output signal required. However, this is not possible with the Schallaufnehmer-filter system due to its narrowband. It is therefore not possible to generate a sinusoidal audio test signal as part of an echo test from the loudspeaker of the mobile phone 20 generated harmonics or harmonic frequencies to measure. The audio test signal is basically in the sensitivity range of the piezoelectric element 18 , and more specifically, the acoustic pickup filter system. Such an audio test signal allows to test whether the audio components of the mobile phone 20 function. For a more accurate quality measurement but also the harmonics must be measured. To see the harmonic parts of the speaker of the mobile phone 20 output signal also to be measured, which in principle outside the narrow-band frequency range of the Schallaufnehmer-filter system but also the piezoelectric element 18 lie, is the audio test signal, which for example in the speaker 31 is output, lowered in its frequency such that the respective harmonics again from the piezoelectric element 18 can be included. More precisely, therefore, in a first step, an echo test with one from the speaker 31 emitted audio test signal performed, the predetermined frequency in the frequency range of the piezoelectric element 18 (and also the filter 23 ) lies. If this test was successfully performed, then a quality measurement is made by analyzing the harmonics of the speaker of the mobile phone 20 delivered signal. This is done by the speaker 31 emitted audio test signal is lowered in its frequency by a factor of 2, in which case by the piezoelectric element 18 the first harmonic or harmonic of the speaker of the mobile phone 20 emitted signal is detected. Subsequently, the frequency of the speaker 31 is lowered by a factor of 3, in which case the second harmonic of the loudspeaker of the mobile phone 20 in the measuring or frequency range of the piezoelectric element 18 or the filter 23 falls. In general, the frequency of the speaker will gradually increase 31 such that the frequency is in each case successively reduced from the predetermined frequency by division by n = 2, 3, 4, 5..., in which case the (n-1) th harmonic is respectively transmitted through the piezoelement 18 is recorded. At the respective measurements of the harmonic components of the speaker of the mobile phone 20 radiated signal become unwanted interference outside the bandwidth of the piezoelectric element 18 or the filter 23 strongly suppressed. Therefore, only the individual harmonic frequencies are measured. The individual measured values can then be added quadratically and used to calculate a harmonic distortion, or they are compared with a limit value.

The invention has been explained in more detail above with reference to preferred embodiments thereof. However, it will be apparent to those skilled in the art that various modifications and changes can be made without departing from the spirit of the invention. The present invention relates to testing of mobile phones. Here, the term "mobile phone" is to be understood very broad and includes in particular also types of devices that have a mobile phone functionality integrated.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19732639 C1 [0003]
• DE 10356087 A1 [0003]
• DE 102004033383 A1 [0003]
• DE 102004049354 B4 [0004]

Claims (23)

Device for performing an audio and / or vibration test on a mobile telephone ( 20 ), characterized by a sound pickup, which during the test by the mobile phone ( 20 ) picks up the emitted signal via the structure-borne noise generated by the signal. Device according to claim 1, characterized in that the sound pickup is a piezoelectric or piezoceramic element ( 18 ). Device according to claim 1 or 2, characterized in that the test is an audio test, and in that the signal is an audio signal transmitted via the loudspeaker of the mobile telephone ( 20 ) is delivered. Apparatus according to claim 3, characterized in that the audio signal is an audio test signal, a call signal, a ringtone or the like. Device according to one of claims 1 to 4, characterized in that the test is a vibration test, and that the signal by a vibration of the mobile phone ( 20 ) is produced. Device according to one of claims 1 to 5, characterized in that the sound sensor on the mobile phone ( 20 ) or is arranged on a directly or indirectly connected to this part of the device. Device according to claim 6, characterized in that the device is an antenna coupler ( 1 ). Apparatus according to claim 7, characterized in that the sound sensor on or in one of the following components of the antenna coupler ( 1 ) is arranged: bracket ( 3 ) for the mobile phone ( 20 ), Positioning carriages ( 4 ) of the holder ( 3 ), Casing ( 2 ) of the antenna coupler ( 1 ). Apparatus according to claim 8, characterized in that the sound pickup within the housing ( 2 ) of the antenna coupler ( 1 ) is mounted, wherein the sound sensor at one of the antenna of the inserted in the intended installation position mobile phone ( 20 ) facing away from the end of the housing ( 2 ) is arranged. Apparatus according to claim 8 or 9, characterized in that the sound sensor within the housing ( 2 ) of the antenna coupler ( 1 ) is mounted, wherein on one side with respect to an antenna of the antenna coupler ( 1 ) the mobile phone used in the intended installation position ( 20 ), and wherein the sound pickup is disposed on the side opposite to the one side with respect to the antenna. Device according to one of claims 1 to 6, characterized in that the device is a shielding ( 30 ). Device according to one of claims 1 to 11, characterized in that the sound pickup an electrical circuit arrangement ( 29 ), the circuit arrangement having an amplifier ( 26 ) and / or a filter ( 23 ) having. Method for performing an audio and / or vibration test on a mobile telephone ( 20 ), characterized in that during the test a 20 ) emitted signal is picked up by a sound pickup on the structure-borne noise generated by the signal. A method according to claim 13, characterized in that the sound sensor is a piezoelectric or piezoceramic element ( 18 ). Method according to Claim 13 or 14, characterized in that the test is an audio test, and in that the signal is an audio signal which is transmitted via the loudspeaker of the mobile telephone ( 20 ) is delivered. A method according to claim 15, characterized in that the audio signal is an audio test signal, a call signal, a ringtone or the like. Method according to one of claims 13 to 16, characterized in that the test is a vibration test, and that the signal by a vibration of the mobile phone ( 20 ) is produced. Method according to one of claims 13 to 17, characterized in that an audio test signal is used to carry out the test, which is sent to the mobile telephone ( 20 ) and over the loudspeaker of the mobile phone ( 20 ) is delivered. A method according to claim 18, characterized in that the audio test signal is a monofrequent audio signal having a predetermined frequency, which corresponds approximately to the resonant frequency of the sound pickup. A method according to claim 19, characterized in that a plurality of audio test signals is used to perform the audio test, wherein one of the plurality of audio test signals has the predetermined frequency, and wherein the further audio test signals have a respective frequency which is different from the predetermined frequency by division by one natural number n, which is greater than or equal to 2, is lowered. A method according to claim 20, characterized in that the respective recorded in the plurality of audio test signals from the sound pickup from the speaker of the mobile phone ( 20 ) are compared with respective predetermined thresholds. A method according to claim 20 or 21, characterized in that from the respectively recorded in the plurality of audio test signals from the sound pickup from the loudspeaker of the mobile phone ( 20 ) signal levels is calculated a distortion factor of the speaker. Use of a sound pick-up to perform an audio and / or vibration test on a mobile phone ( 20 ), with the sound pickup on during the test by the mobile phone ( 20 ) picks up the emitted signal via the structure-borne noise generated by the signal.

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