DE10200782C1 - Testing circuit for plug-in cable connection between radio and audio amplifier uses evaluation of DC voltage received at radio end of cable connection from virtual earth point at amplifier end - Google Patents

Abstract

The testing circuit has a DC voltage generator (8) at the input of the audio amplifier, for providing a virtual earth point, with an evaluation circuit (13) at the radio end of the plug-in cable connection receiving the DC voltage for evaluation via a signal feedback line (12).

Description

The invention relates to a circuit arrangement for testing a single or multi-channel connector cable between a radio and a Audio amplifier.

Radio audio amplifiers are increasingly being used in motor vehicles. Combinations built in, with the radio at the front in the area of the Armatu renbretts and the audio amplifier in a remote, hidden place is ordered. Radio and audio amplifiers are usually about a Mehrka nal connector cable connected together. This connector cable runs from a rear radio connector to the ent speaking mating connector on the audio amplifier, and due to the installation both components completely hidden and after finishing the Motor vehicle inaccessible. Now and then it happens that the plug connecting line is not plugged in or for whatever reason always solved. This is done after the completion of the motor vehicle fixed, complex work is required to correct this error.

From DE 199 41 845 C1 is a connector for a flexible, flat line arrangement voltage, which is fixed between a connector body and a latch, be knows, with which the electrical contact is reliable and simple between the conductors of the flat data line arrangement and the contact pins of the plug can be checked. The connector has two contacts on a connector body. The contacts are counter contacts assigned to a bolt. The counter contacts are on a short circuit bridge connected. In this way, the correct support of the latch can be opened the connector body and thus the electrical contact with its con check clock pins.

The invention is based on the problem, a simple remedy here to create and a way to easily check whether the plug connecting line is inserted, so that early on such a test can be carried out after the installation of the two elements.

The solution to this problem is in a circuit arrangement mentioned type according to the invention provided that at the input of the audio amplifier by means of at least one DC voltage generating device a virtual ground point is realized, the DC voltage when plugged in  Connector cable via a signal feedback line to a radio the evaluation circuit provided on the side is decoupled and evaluated there.

In the circuit arrangement according to the invention, the direct voltage generation device, the amplifier side a virtual mass point forms, generates a DC voltage, which via a signal feedback tion line parallel to the radio signal to the amplifier Radio signal line is guided (the already existing one is suitable for this Ground line), to an evaluation circuit provided on the radio which it receives and evaluates. Since this signal return line in the connector cable is guided, so if the same voltage signal is not present at the radio evaluation circuit, he be known that the connector cable is not plugged in, so none Connection between radio and audio amplifier is given, which is the Anle enable the DC voltage signal to the evaluation circuit would. This is a simple way of recognizing the Plug state of the connecting cable implemented.

The DC voltage generating device which is usually present in audio amplifiers or at their inputs is expediently used as the DC voltage generating device for generating a DC voltage offset for an operational amplifier located at the amplifier input. This DC voltage generating device is present on the amplifier input side anyway, since it generates a DC offset on the input-side operational amplifier by which the LF signal is modulated. So there are no additional generating means required for DC voltage generation, rather one relies on the given circuit elements. It is only necessary to couple this DC voltage, which is generated anyway, to the radio. The DC voltage generating device expediently generates a DC voltage of U _B / 2, where U _{B is} the DC voltage supplied from a battery voltage, in particular the motor vehicle battery derived supply voltage of the operational amplifier. The evaluation circuit expediently contains a capacitor, via which the DC voltage can be coupled out when the plug connection line is inserted. When the DC voltage signal is present, this capacitor prevents a current from flowing and thus power being consumed.

It is also expedient for reliable detection of the plug-in state if the evaluation circuit comprises an operational amplifier to which the decoupled direct voltage and a reference voltage are present, and if a processor is provided that evaluates the output signal of the operational amplifier. The operational amplifier, which operates here as a differential amplifier, amplifies the differential signal resulting from the presence of both voltages, which is dependent on the selected voltages. If U _B / 2 is present at one operational amplifier input and at the other U _Ref and both voltages are of the same magnitude, there is no difference, ie the operational amplifier output signal is zero. If the connector line is not plugged in, then only U _{Ref is present} , so that a corresponding output signal is set at the operational amplifier, which can then be evaluated on the processor. Alternatively, there is the possibility of designing the evaluation circuit as a window comparator.

The circuit arrangement described evaluates the recognition of the Ste only the presence of a DC voltage in the the signal return line formed signal path to the plugged Diagnose connection between radio and audio amplifier. At no Using this detection option, it is also possible to identify errors that affect the another signal line, i.e. the radio signal line, is after one advantageous development of the invention provides that the radio signal Line over which the radio output signals are given and the signal feedback line via which the DC voltage is coupled out with a differential amplifier of the evaluation circuit are connected, the Output signal can be evaluated in the evaluation circuit, one of the Ver signal lines with the differential amplifier via a voltage divider is bound. In this embodiment of the invention, both signal lines are conditions evaluated using the differential amplifier. Usually, if so both signal lines are plugged in or the radio signal line is not under  is broken (e.g. if the line is accidentally bent or the same can occur), is the DC voltage on both signal lines lines identical, since the DC voltage generating device gives the DC voltage on the amplifier-side operational amplifier, both signal lines due to the internal connection of the operation amplifier with the DC voltage signal. By the provided voltage divider there is still a voltage difference at the input of the differential amplifier, which more or less ver also strengthens at its exit. However, is the positive signal line interrupted (of course, the same applies to an interruption the negative signal feedback line), the voltage changes difference at the input of the differential amplifier, which is a corresponding Än change in the output voltage. Based on the change (Span voltage becomes smaller or larger), it can also be detected which che of the two signal lines is interrupted because one of the signal lines is given to the differential amplifier via the voltage divider. This proposed design of the invention therefore not only offers the possibility ability to record different errors, but also based on the output voltage of the differential amplifier between different to be able to distinguish between those types of errors.

It is useful as a differential amplifier in this invention design of the operational amplifiers of those already described at the beginning Evaluation circuit used. To assign the via the radio signal line led to the differential amplifier DC voltage signal is expedient A capacitor is also provided in this case.

As a rule, multi-channel connecting cables are used is, according to an advantageous design of the invention for each channel comprising a radio signal line and a signal return line separate DC voltage supply device with its own channel orderly evaluation device provided.

Further advantages, features and details of the invention result from the embodiment described below and based on the Drawings. Show:

Fig. 1 shows a circuit arrangement of a first embodiment, and

Fig. 2 shows a circuit arrangement of a second embodiment.

Fig. 1 shows a circuit arrangement 1 according to the invention showing a first embodiment. The circuit components are shown on the radio side R and the amplifier side V. On the radio side, an operational amplifier 2 is initially provided as a driver for the radio output signal, which is given via a resistor 3 to the radio signal line 4 of a connector 5 between the radio R and the amplifier V. becomes. About this connector line 5 , the radio R and the audio amplifier V, which are separate and spaced from each other Ge devices, connected. The radio output signal is given via a resistor 6 to an operational amplifier 7 provided at the amplifier input and there to the negative signal input. At the negative signal input there is a DC voltage signal generated via a DC voltage generating device 8 . For this purpose, the resistor 9 is connected to a battery, not shown, when installed in a motor vehicle with the motor vehicle battery, which supplies the battery voltage UB (usually +15 V). About the two resistors 9 , which act as a voltage divider, the battery voltage is halved to U _B / 2 and over a further resistor 10 , which is closed via a capacitor 11 , to the positive input of the operational amplifier 7 . At the same time, the DC voltage signal is sent via a signal feedback line 12 (here an already existing ground line) to an evaluation device 13 on the radio side. This signal feedback line 12 , which of course continues in the connector line 5 , applies the DC voltage signal U _B / 2 to the positive input of an operational amplifier 14 of the evaluation circuit 13 . The coupling takes place via the capacitor 15 , which prevents a current from flowing here.

A reference voltage signal U _{Ref is present} at the negative input of the operational amplifier 14 . A microprocessor 16 , which evaluates the output signal of the operational amplifier 14, is connected downstream of the operational amplifier.

In the plugged-in state, that is to say when the plug-in connection line 5 is correctly plugged in both on the radio and on the amplifier side, the direct voltage signal, which is given via the signal feedback line 12 to the evaluation device 13 , is present. Is z. B. U _B / 2 equal to U _Ref , there is no output signal when the operational amplifier functions as a differential amplifier. According to the definition, a correct connection would be detected in this case. However, if the connector cable is not plugged in on the radio or amplifier side, the DC voltage signal cannot be given to the evaluation device 13 , so that there a voltage difference at the operational amplifier 14 is detected and correspondingly recognized on the microprocessor side and output as an error signal.

Fig. 2 shows a further circuit arrangement according to the invention 17th Here, too, an operational amplifier 18 is provided on the radio side, which outputs the radio output signal to the radio output via a resistor 19 and a large capacitance 20 , from where it is connected via the connecting line 21 and its radio signal line 22 to the input of the amplifier V and there to the negative operational amplifier input of the operational amplifier 23 is given. Here, too, U _B / 2 is present at the positive operational amplifier input, which is generated via the DC voltage generating device 24 . At the same time U _B / 2 is transmitted via the signal feedback line 25 of the plug connection line 21 to the radio and its evaluation device 26 . Here too, the capacitance 27 prevents an undesired current from flowing via the signal return line.

On the positive input of the operational amplifier 28 of the evaluation device 26 , the direct voltage signal U _B / 2 is also given via the connecting line 29 . This signal is present both at the positive and at the negative input of the operational amplifier 23 , due to its internal connection, ie U _B / 2 can also be tapped via the radio signal line. The DC voltage signal is separated from the output of the operational amplifier 18 via the capacitance 20 . While the connecting line 29 is given directly to the positive input of the operational amplifier 28 , which works here as a differential amplifier, the DC voltage signal is fed via the signal feedback line 25 with the interposition of a voltage divider, formed from the two resistors 30 . Furthermore, a further resistor 31 is provided, which serves to ensure that a defined DC voltage can be set at the input of the operational amplifier 28 in the event of a fault "radio signal line 21 interrupted".

In the normal case, so if the connector line 21 is correctly inserted, the DC voltage on the radio signal line 22 and the signal return line 25 is identical. The voltage divider, formed by the two resistors 30 , results in a voltage difference at the input of the differential amplifier 28 , which is also more or less amplified at its output and can be evaluated there by the microprocessor 32 .

If one of the two signal lines 22 or 25 is interrupted, the voltage difference at the input of the differential amplifier 28 changes, which results in a corresponding change in the output voltage. Depending on the change, the output voltage becomes larger or smaller, depending on which voltage signal disappears due to the line interruption. I.e. it is possible to see from the size of the output signal of the differential amplifier 28 which of the two lines is actually interrupted. If both signal lines are interrupted and there is no DC voltage and differential amplifier, the differential voltage is zero, which also results in the output voltage being zero.

It is therefore possible with this embodiment of the invention, on the one hand - as in the circuit arrangement according to FIG. 1 - to detect the state "plugged - not plugged in" of the signal connection line, but moreover it can also be detected which line within a signal channel (the each consists of a radio signal line and a signal feedback line) is interrupted.

In conclusion, it should be noted that the circuit arrangements shown each show those for a signal channel. As a rule, a radio and an audio amplifier are connected via a multi-channel connecting cable. A circuit arrangement as shown in FIG. 1 or 2 is to be provided for each channel.

Claims (10)

1. Circuit arrangement for testing a single-channel or multi-channel connecting line between a radio and an audio amplifier, characterized in that a virtual ground point is realized at the input of the audio amplifier by means of at least one DC voltage generating device ( 8 , 24 ), the DC voltage of which when the connector line is plugged in ( 5 , 21 ) are coupled out via a signal feedback line ( 12 , 25 ) to an evaluation circuit ( 13 , 26 ) provided on the radio and evaluated there. 2. Circuit arrangement according to claim 1, characterized in that the DC voltage generating device ( 5 , 21 ) is used to generate a DC voltage offset for an operational amplifier ( 7 , 23 ) located at the amplifier input. 3. Circuit arrangement according to claim 2, characterized in that the DC voltage generating device ( 5 , 21 ) generates a DC voltage of U _B / 2, where U _{B is} the DC voltage supplied by a battery or a voltage derived from the battery voltage. 4. Circuit arrangement according to one of the preceding claims, characterized in that the evaluation circuit ( 13 , 26 ) comprises a capacitor ( 15 , 27 ) via which the DC voltage can be coupled out when the plug-in connection line ( 12 , 25 ). 5. Circuit arrangement according to one of the preceding claims, characterized in that the evaluation circuit ( 13 ) comprises an operational amplifier ( 14 ) to which the decoupled DC voltage and a reference voltage (U _Ref ) are applied, and the output signal is evaluated. 6. Circuit arrangement according to one of claims 1 to 4, characterized, that the evaluation circuit is designed as a window comparator. 7. Circuit arrangement according to one of the preceding claims, characterized in that the radio signal line ( 22 ), via which the radio output signals are given, and the signal feedback line ( 25 ), via which the DC voltage is coupled out, with a differential amplifier ( 28 ) of the evaluation circuit ( 26 ) are connected, the output signal of which can be evaluated in the evaluation circuit ( 26 ), one of the signal lines being connected to the differential amplifier ( 28 ) via a voltage divider ( 30 ). 8. Circuit arrangement according to claim 7, characterized in that the operational amplifier of the evaluation circuit ( 26 ) serves as the differential amplifier ( 28 ). 9. Circuit arrangement according to claim 7 or 8, characterized in that a capacitor ( 20 ) is provided for separating the via the radio signal line ( 22 ) to the differential amplifier ( 28 ) guided DC voltage signal. 10. Circuit arrangement according to one of the preceding claims, characterized,  that with a multi-channel connector cable for each channel comprising a radio signal line and a signal return line a separate DC voltage supply device with channel ner assigned evaluation device is provided.