FR2950146A1 - Tested device e.g. single ended loudspeaker, diagnostic device for use in e.g. radio communication terminal, has determination unit determining current operation state of ohmic device based on diagnostic signal - Google Patents

Abstract

Device for diagnosing a device under test, said device being tested having an ohmic load (100) between first and second terminals (SPK +, SPK-). The diagnostic device comprises: means for generating (202) an activation signal; a first switch connected in series, on a first branch, between a power source and the first terminal of the device under test, the first switch passing into a closed state when it receives, on a control input, a signal confused with or function of the activation signal; the second terminal of the device under test being connected directly or indirectly, on a second branch, to a ground; means for receiving (203) a diagnostic signal, a function of a signal present on the first terminal of the device under test, when the first switch receives the control signal; means for determining (204) a current operating state of the device under test, as a function of the diagnostic signal.

Description

Device for diagnosing an ohmic device, equipment and corresponding electronic circuit. FIELD OF THE INVENTION The field of the invention is that of devices having an ohmic load (also called ohmic devices). More specifically, the invention relates to a diagnostic technique for obtaining information on the operating state of an ohmic device. The invention has many applications, such as, for example, in the field of acoustics, the diagnosis of the state of a loudspeaker.

More generally, it can be applied in all cases where it is important to obtain a fine diagnosis of an ohmic device. BACKGROUND OF THE INVENTION In the remainder of this document, the problem that exists in the field of audio systems, to which the inventors of the present patent application have been confronted in the context of the European eCall project, is particularly focused in the following. . The invention is not limited, of course, to this particular field of application, but is of interest for any diagnostic technique having to deal with a similar or similar problem (ie having to perform a diagnosis of a device having an ohmic load) . For example in the context of operating test, remote, a medical device (insulin pump, oxygenation equipment, etc. ..), the invention allows a better coordination of help in case of detection of failure of said device . As a reminder, the eCall project is a project of the European Commission to improve transport safety, allowing motorists who would be involved in a collision to obtain rapid assistance wherever they are on the territory of the Union. European. The accident will activate sensors on board the vehicle that will initiate an emergency voice call (E112) via the mobile network to the local emergency services. Thus, a communication between the motorist and the assistance will be established using a modem of type "in-band voice-channel" embedded, which will also transmit the position of the vehicle, and will signal the possible deployment of the airbag, the vehicle identification number and other necessary information. This modem allows you to use existing mobile networks to facilitate the rapid deployment of an end-to-end eCall solution between vehicles and emergency and assistance services. In the event of an accident, if the speaker (s) have been damaged (s), whether the driver can hear or not the questions of the rescuers is essential to establish an initial assessment of the damage caused by the accident. 'accident. It then appears necessary to be able to provide a technique for remotely checking the correct operation or not of at least one speaker. There is known in the state of the art, a technique to overcome this problem.

This technique, well known to those skilled in the art, consists of using an audio loop: a diagnostic device controls the transmission of a sound signal predefined by a speaker to be tested, the transmitted signal is then received by a sensor which transmits the signal to the diagnostic device so that the latter performs processing on the received signal. Depending on the result obtained, a diagnosis of the loudspeaker is established by the diagnostic device. A disadvantage of this solution is that it requires a significant energy consumption. Indeed it is necessary to operate the loudspeaker in order to establish a diagnosis. Another disadvantage of this solution is that it requires a sensor that contains many electronic components (including a micro-audio). Another disadvantage of this solution is that it is sensitive to interference: if a person near the sensor speaks, or if noise from other sources is detected by the sensor, the diagnostic device can not provide a accurate diagnosis.

Another disadvantage of this solution is that it has a diagnostic granularity too coarse. Indeed, if the sensor is too simple, the measurements used only allow to know if a speaker is functional or not, without further details. Finally, another disadvantage of this solution is that it applies only to the test of a loudspeaker (since it is based on an audio loop) and can not be generalized to the test of any type of ohmic device. OBJECTIVES OF THE INVENTION The invention, in at least one embodiment, has the particular objective of overcoming these various disadvantages of the state of the art. More specifically, in at least one embodiment of the invention, one objective is to provide a diagnostic technique that is easy to implement (ie does not require the use of a large number of sophisticated hardware components) making it possible to perform a diagnosis of an ohmic device (in particular but not exclusively a loudspeaker). Another objective of at least one embodiment of the invention is to provide such a diagnostic technique that consumes little energy and is only slightly sensitive to interference. At least one embodiment of the invention also aims to provide such a diagnostic technique for performing an accurate diagnosis of the state of a speaker and not modifying said speaker (ie it it is not necessary to incorporate therein wires for transmitting and receiving signals). Another objective of at least one embodiment of the invention is to provide such a diagnostic technique that does not require an audio loop. At least one embodiment of the invention also aims to provide a technique that is compatible with any type of loudspeakers as well as more generally any device with an ohmic load. 4. DISCLOSURE OF THE INVENTION In a particular embodiment of the invention, there is provided a device for diagnosing a device tested, said device tested having an ohmic load between first and second terminals (SPK +, SPK-). said diagnostic device comprises: means for generating an activation signal; a first switch connected in series, on a first branch, between a power source and the first terminal of the device under test, the first switch going into a closed state when it receives, on a control input, a confused control signal; with or function of the activation signal; the second terminal of the device under test being connected directly or indirectly, on a second branch, to a ground; means for receiving a diagnostic signal, as a function of a signal present on the first terminal of the device under test, when the first switch receives the control signal; means for determining a current operating state of the device under test, as a function of the diagnostic signal. The general principle of the invention is based on a completely new and inventive diagnostic approach to the operating state of a tested device having an ohmic load via the use of a first switch. Indeed, when the switch, itself having an ohmic load, is closed following the reception of an activation signal on a control input, a resistive divider bridge is formed and the measurement of a voltage value at the first terminal of the device under test (or a function thereof) by receiving means enables the determining means to diagnose the current state of the tested device among different states. This solution is therefore not very complex to implement.

In addition, this solution is generic because it works with any speaker on the market and more generally with any device with an ohmic load. Indeed, this device is not invasive: it is not necessary to change the structure of the device tested to obtain a diagnosis of it. In addition, the activation signal is not an audio signal. Therefore, this technique does not require the use of an audio processing unit, nor the use of an amplifier which are complex hardware units (because using many sophisticated electronic components). Advantageously, such a diagnostic device comprises a second switch connected in series between the second terminal (SPK-) of the device under test and the ground, the second switch passing into a closed state when it receives, on a control input, said control signal. Thus, a second switch is positioned within the diagnostic device on the second branch. Therefore, the second terminal of the device under test is indirectly connected to ground. The use of a second switch makes it possible to reduce the ohmic value of the other elements constituting said diagnostic device. This particular embodiment applies in particular to a device powered, in normal operation, differential i.e via two inputs (which is the case for example, a speaker with two terminations or "differential" in English). In a variant, the second terminal (SPK-) of the device under test is connected directly to ground. This makes it possible to create a diagnostic device comprising only a few elements (and thus consuming only little energy). This variant applies in particular to a device powered, in normal operation, via a single input (which is the case for example, a loudspeaker to a termination or "single ended" in English). According to an advantageous characteristic, the diagnostic device comprises a resistive divider bridge, making it possible to obtain the diagnostic signal as a function of the signal present on the first terminal of the device under test. Thus, the use of a resistive divider bridge makes it possible to obtain a given voltage lower than that which is at the input of the resistive bridge. By choosing particular resistance values, the value of the diagnostic signal can be checked. This is particularly advantageous when the means for receiving a diagnostic signal can not withstand too high a voltage. Finally, the fact of using a resistive divider bridge with resistance values much greater than the value of the ohmic load of the device under test makes it possible to limit the interference between the resistive divider bridge and the device under test.

According to an advantageous characteristic, the diagnostic device comprises, in at least one of said first and second branches, at least one resistor connected in series. Thus, in one embodiment of the invention, the addition of one or more resistors in series with the one or more switches makes it possible to reduce the stresses (on the internal resistances, ...) bearing on them. In particular, this makes it possible to choose a transistor having a lower cost due to the small size of its internal resistance. According to an advantageous characteristic, the diagnostic device comprises an analog / digital converter, making it possible to digitize said diagnostic signal before reception by the reception means.

Thus, through the use of an analog-to-digital converter, the diagnostic signal becomes a digital signal (encoded on several bits). The means for receiving and determining an operating state of the device under test can then use specific hardware components (for example a DSP (for "Digital Signal Processor" or "Digital Signal Processor" in French)) allowing to speed up the determination of a diagnosis.

According to an advantageous characteristic, the diagnostic device comprises a voltage regulator comprising a voltage input connected to said power source and a voltage output connected to the first switch, said regulator delivering a supply signal on the voltage output when it receives, on a control input, said activation signal.

The delivery of the power signal to the first switch (and the second switch if there is one) is therefore controlled by the value of the activation signal. Thus, the use of a voltage regulator saves the energy consumption of said diagnostic device. Indeed, the activation signal is not issued continuously, it is not necessary to continuously supply the diagnostic device with the source. According to an advantageous characteristic, for such a diagnostic device, the supply signal also constitutes the control signal. Thus, the power supply signal and the activation signal being merged, this advantageously makes it possible to minimize the number of wires within the diagnostic device. In a particular embodiment of the invention, the diagnostic device is remarkable in that the device under test is a loudspeaker. Thus, unlike the solutions of the state of the art cited above, it is proposed a technique requiring only a few hardware resources (transistors, resistors) to perform a fine diagnosis. Advantageously, the diagnostic device is remarkable in that the means for determining an operating state of the device under test comprise means for comparing the diagnostic signal with at least two ranges of values, each value range being associated with a state. possible operation of the device under test.

Advantageously, such a diagnostic device is remarkable in that the means for determining an operating state of the device under test comprise means for comparing the diagnostic signal with five ranges of values each associated with one of the five operating states. following possibilities: - the tested device is functioning normally; the tested device is in open circuit; the device under test has a short circuit between the first and second terminals of the device under test; the device under test has a short circuit between the first terminal of the device under test and the ground; the device under test has a short circuit between the second terminal of the device under test and the ground. Thus, it is possible to diagnose five different states. In another embodiment, the invention relates to equipment comprising an electronic module controlling an ohmic device, said equipment further comprises a diagnostic device, said ohmic device being said device tested.

Advantageously, such equipment comprises switching means between: a first mode of operation, in which the electronic module controls the ohmic device; and a second mode of operation, in which the diagnostic device tests the ohmic device.

Advantageously, in such equipment, the electronic module comprises said means for receiving a diagnostic signal and said means for determining an operating state of the device under test. Advantageously, such equipment is used when the device under test is a loudspeaker.

Advantageously, such equipment may be a radiocommunication terminal, and the electronic module may be a radiocommunication module. In another embodiment, the invention relates to an electronic circuit comprising a diagnostic device as described above. 5. LIST OF FIGURES Other features and advantages of the invention will appear on reading the following description, given by way of indicative and nonlimiting example, and the appended drawings, in which: FIG. 1 presents a block diagram; context (ohmic device and a microcontroller) where the present invention applies. - Figure 2 shows a block diagram of a diagnostic device according to a first particular embodiment of the invention comprising two switches; - Figure 3 shows a block diagram of a diagnostic device according to a second particular embodiment of the invention, implementing a resistive divider bridge in association with two switches; - Figure 4 shows a block diagram of a diagnostic device according to a third particular embodiment of the invention, implementing an analog-digital converter in combination with two switches; FIG. 5 shows a block diagram of a diagnostic device according to a fourth particular embodiment of the invention, implementing a regulator in association with two switches; - Figure 6 shows a block diagram of a diagnostic device according to a fifth particular embodiment of the invention, implementing a controller and resistors in combination with two switches; FIG. 7 is a circuit diagram of a diagnostic device of a two-terminal loudspeaker (or "differential" in English) according to a sixth particular embodiment of the invention, implementing a regulator, two switches using transistors and resistors; FIG. 8 shows, in tabular form, the results of the measurements at the output of the diagnostic device of FIG. 7, according to different cases of figures when in the state of said loudspeaker; FIG. 9 is a circuit diagram of a device for diagnosing a speaker with a termination (or "single ended" in English) according to a seventh particular embodiment of the invention, implementing a regulator, a switch using transistors and resistors. DETAILED DESCRIPTION In all the figures of this document, the elements and identical steps are designated by the same numerical reference. Figure 1 shows a synoptic of the context where the present invention applies. An ohmic device (100) having an ohmic load is connected to an electronic module (101) which controls it. FIG. 2 presents a block diagram of a diagnostic device according to a first particular embodiment of the invention, comprising two switches. A first switch is connected in series between a power source and the first terminal (SPK +) of the ohmic device (100). It includes a first control input (205). A second switch is connected in series between the second terminal (SPK-) of the ohmic device (100) and a ground. It includes a second control input (206). An electronic module wishing to perform a diagnosis of a device (100) generates an analog EN-DIAG-LOAD signal via generation means (202). When the first (200) and second (201) switches (of electronic, mechanical or other types) each go to a so-called closed state following the reception of the analog EN-DIAG-LOAD activation signal on the first and second input of control (205 and 206), this induces the creation of a resistive divider bridge. Thus, the value of the diagnostic signal RESULT-DIAG-LOAD obtained by the reception means (203), from the measurement of the voltage on the first terminal (SPK +) of the ohmic device (100), makes it possible to characterize the state of the ohmic device (100) using determining means (204); the electronic module (101) can then perform the appropriate actions according to the diagnostic signal management policy. It may request, for example, the emission of an SMS (acronym for "Short Message Service" or "text messaging service" in French) to warn a third of the state of the ohmic device (100 ). Note that the (temporal) frequency at which the EN-DIAG-LOAD activation signal is sent is defined in the activation signal management policy. The granularity of this frequency is a function of the need to obtain or not frequently information on the operating state of the ohmic device (100). FIG. 3 presents a block diagram of a diagnostic device according to a second particular embodiment of the invention, implementing a resistive divider bridge (300) in association with two switches (200 and 201). Thus, with respect to FIG. 2, a resistive divider bridge (300) is added to the first terminal (SPK +) of the ohmic device (100) which comprises two resistors R1 and R2, chosen so that the attenuation ratio obtained at the output of said divider bridge corresponds to the range of values accepted by the reception means (203).

Advantageously, it is necessary to choose values, for the resistances of the divider bridge (300), very large compared to the value of the load of the device (100) to avoid interference. FIG. 4 presents a block diagram of a diagnostic device according to a third particular embodiment of the invention, implementing an analog / digital converter (400) in association with two switches (200 and 201). As a reminder, an analog-digital converter (ADC or ADC for "analog to digital converter" in English) has the function of generating from an analog value, a numerical value (encoded on several bits), proportional to the analog value Entrance. Thus, with respect to FIG. 2, a CAN (400) is used on the first terminal (SPK +) of the device such that the analog signal of the first terminal (SPK +) is converted into a digital diagnostic signal RESULT-DIAG -LOAD received by receiving means and processed by determining means comprising hardware (or "hardware" in English) DSP type, comparator, etc. to accelerate the time to obtain a diagnosis for the electronic module (101). FIG. 5 presents a block diagram of a diagnostic device according to a fourth particular embodiment of the invention, implementing a regulator in association with two switches.

A first switch is connected in series between a regulator (500) and the first terminal (SPK +) of the ohmic device (100). It further comprises a first control input (504). A second switch is connected in series between the second terminal (SPK-) of the ohmic device (100) and a ground. It further comprises a second control input (505). A regulator (500) includes a first input (501) connected to a power source, a second input (502) which receives the ENDIAG-LOAD enable signal as appropriate, and an output (503) which provides a signal both food and control. An electronic module wishing to perform a diagnosis of a device (100) generates an analog EN-DIAG-LOAD signal via generation means (202).

That is received on a second input (502) of the regulator (500). The voltage regulator (500) provides an output voltage (output of 503) that is fixed and non-zero, if the EN-DIAG-LOAD activation signal is output in the second input (502) of the controller, or zero if the EN-DIAGLOAD activation signal is not delivered in the second input (502) of the controller.

The fact of using a regulator makes it possible to limit the electrical consumption of the circuit. When the supply and control signal is emitted at the output of the output (503), if it is non-zero, the first (200) and second (201) switches each go to a closed state following reception. of said signal, on a first (504) and a second (505) control input, thereby creating a resistive diverted power supply bridge. Thus, the value of the diagnostic signal RESULT-DIAG-LOAD obtained by the reception means (203), from the first terminal (SPK +) of the ohmic device (100), makes it possible to characterize the state of the ohmic device (100). ) using determining means (204).

FIG. 6 shows a block diagram of a diagnostic device according to a fifth particular embodiment of the invention, implementing a regulator and resistors in association with two switches. This figure is an improvement of the device shown in Figure 5: two resistors R1 and R2 are added in series on either side of the switches thus reducing the constraints yet on said switches.

FIG. 7 presents a circuit diagram of a diagnostic device of a two-terminal speaker (or "differential" in English), of 8 ohm / 1W, according to a sixth particular embodiment of the invention, a regulator, two switches using transistors and resistors. This scheme is an instantiation of Figure 5 using electronic components. In this electrical diagram, there are two switches comprising: - in the first switch (200): a transistor T100 MOSFET (for "Metal Oxide Semiconductor Field Effect" in English, or "field effect transistor" in French) type P and a bipolar transistor T102 NPN mounted as a common emitter; the collector of the bipolar transistor is connected to the gate of the MOSFET transistor; the drain of the MOSFET transistor is connected to the first speaker terminal (SPK +) and the source of the transistor is connected to the regulator; in the second switch (201): an N-type MOSFET transistor T101 mounted in a common source whose gate to a voltage source delivered by the regulator (500), the source is connected to a ground (GND) and the drain is connected to the second speaker terminal (SPK-). The MOSFET transistors each have an internal resistor (RDSon) of 6 ohm. In addition there is also a resistive divider bridge (consisting of resistors R100 and R101) and a U100 controller.

When the EN-DIAG-LOAD activation signal is received by the controller, it then delivers a voltage of 5V in the diagnostic circuit. This then causes the saturation of transistors T102, T100 and T101 (i.e they each go to a closed state). More precisely, when the voltage of 5V is delivered, the transistor T102 is saturated, then inducing the switching of the transistor T100. Then, the voltage Vgs, voltage between the gate and the source of the MOSFET transistors, is 5V. Therefore, the transistor T101 also switches. A resistance bridge of 6 + 8 + 6 ohm is thus obtained (in fact, the MOSFET transistors chosen have an internal resistance of 6 ohm). A current of approximately 250 mA is then obtained, the voltage on SPK + is equal to (8 + 6) * 5 / (8 + 6 + 6) = 3.5V. This induces then that the value of the signal RESULT-DIAG-LOAD is 100 * 3.5 / (100 + 180) = 1.25V (against 1.16V in simulation this being certainly due to the errors of simulation with software SPICE (acronym of "It seems that this is due to the fact that the MOSFET transistors have an impedance higher than 6 ohm).

Thus, by measuring the voltage at the output of the resistive divider bridge i.e by measuring the value of the signal RESULT-DIAG-LOAD at the first terminal (SPK +), it is possible to obtain information on the operating state of the loudspeaker. In particular, information is obtained which is detailed in the following figure. FIG. 8 presents, in tabular form, the results of the measurements of the diagnostic signal of FIG. 7, according to different cases as to the state of said loudspeaker. Thus, it can be seen that the diagnostic device, in this embodiment of the invention, can detect five different situations: the loudspeaker is connected (ie no link fails) when an analog signal is measured diagnosis having a value of 1.16V; - the loudspeaker is in open circuit when measuring an analog diagnostic signal having a value of 1.78V; the loudspeaker is short-circuited and more precisely said short circuit occurs between the SPK + and SPK-termination if an analog diagnostic signal having a value of 0.64V is measured; - the speaker is short-circuited more precisely said short circuit occurs between the SPK + terminal and ground if one measures a diagnostic analog signal having a value of OV; - the speaker is in short-circuit more precisely said short circuit occurs between the terminal SPK- and ground if one measures a diagnostic analog signal having a value of 0.94V. Once a short circuit has been detected, within the framework of an e-call application, the manufacturer can provide, in a control software, for generating a fault SMS or, more generally, for a service information item to inform the speaker failure. The manufacturer of the vehicle may replace the defective element if necessary. Finally, in another embodiment of the invention, with different characterizing values for the components, the diagnostic device can be used to perform the diagnosis of alarms (home alarms or fire alarms). Thus, as soon as a failure is detected (several types of failures that can be detected unlike the solutions of the state of the art), the user or the manager of these alarms can take the appropriate measures. FIG. 9 shows a circuit diagram of a diagnostic device of a speaker with a termination (or "single-ended" in English) according to a seventh particular embodiment of the invention, implementing a regulator, a switch using transistors and resistors. By substituting the switch, represented by the block 201 in FIGS. 2 to 6 with a simple wired connection, the diagrams representing diagnostic devices according to particular embodiments of the invention, comprising a switch 200, are obtained. in Figure 7, in this diagram, the second terminal of the speaker (SPK-) is connected to a ground. The other elements constituting the diagram of FIG. 7 are found together with a series resistance with the first switch (200).

Resistor R105, optional, limits the stress on the choice of the MOSFET component. The resistance bridge (R100 / R101), which is also optional, allows you to adapt the analog voltage to the instrumentation that will read the output voltage.

Claims (16)

REVENDICATIONS1. Device for diagnosing a device under test, said device having an ohmic load (100) between first and second terminals (SPK +, SPK-), said diagnostic device being characterized in that it comprises: - generation means (202) an activation signal; a first switch connected in series, on a first branch, between a power source and the first terminal of the device under test, the first switch passing into a closed state when it receives, on a control input, a signal confused with or function of the activation signal; the second terminal of the device under test being connected directly or indirectly, on a second branch, to a ground; means for receiving (203) a diagnostic signal, a function of a signal present on the first terminal of the device under test, when the first switch receives the control signal; means for determining (204) a current operating state of the device under test, as a function of the diagnostic signal. 2. Diagnostic device according to claim 1, characterized in that it comprises a second switch connected in series (201) between the second terminal (SPK-) of the device under test and the mass, the second switch passing into a closed state when it receives, on a control input, said control signal. 3. Diagnostic device according to any one of claims 1 or 2, characterized in that it comprises a resistive divider bridge (300) for obtaining the diagnostic signal as a function of the signal present on the first terminal of the device. tested. 4. Diagnostic device according to any one of claims 1 to 3, characterized in that in at least one of said first and second branches, at least one resistor is connected in series (R1 and / or R2). 5. Diagnostic device according to any one of claims 1 to 4, characterized in that it comprises an analog / digital converter (400) for digitizing said diagnostic signal before reception by the receiving means. 6. Diagnostic device according to any one of claims 1 to 5, characterized in that it comprises a voltage regulator (500) comprising a voltage input (501) connected to said power source and a voltage output (503) connected to the first switch (200), said regulator delivering a supply signal to the voltage output when it receives, on a control input, said activation signal. 7. Diagnostic device according to claim 6, characterized in that the supply signal also constitutes the control signal. 8. Diagnostic device according to any one of claims 1 to 7, characterized in that the device under test is a loudspeaker. 9. Diagnostic device according to any one of claims 1 to 8, characterized in that the means for determining an operating state of the device under test comprises means for comparing the diagnostic signal with at least two ranges of values, each value range being associated with a possible operating state of the device under test. Diagnostic device according to claim 9, characterized in that the means (204) for determining an operating state of the device under test comprise means for comparing the diagnostic signal with five ranges of values each associated with one the following five possible operating states: - the tested device is operating normally; the tested device is in open circuit; the device under test has a short circuit between the first and second terminals of the device under test; the device under test has a short circuit between the first terminal of the device under test and the ground; the device under test has a short circuit between the second terminal of the device under test and the ground. 11. Equipment comprising an electronic module controlling an ohmic device, said equipment being characterized in that it further comprises a diagnostic device according to any one of claims 1 to 10, said ohmic device being said device tested. 12. Equipment according to claim 11, characterized in that it comprises switching means between: - a first mode of operation, wherein the electronic module controls the ohmic device; and a second mode of operation, in which the diagnostic device tests the ohmic device. 13. Equipment according to any one of claims 11 and 12, characterized in that the electronic module comprises said means for receiving a diagnostic signal and said means for determining an operating state of the device under test. 14. Equipment according to any one of claims 11 to 13, characterized in that the device under test is a loudspeaker. 15. Equipment according to any one of claims 11 to 14, characterized in that it is a radiocommunication terminal, and in that the electronic module is a radiocommunication module. 16. Electronic circuit characterized in that it comprises a diagnostic device according to any one of claims 1 to 10.20