DE4323619C1 - Apparatus for the transmission of a plurality of sensor signals to an electronic control device - Google Patents

Abstract

A description is given of an apparatus for the transmission of a plurality of sensor signals to an electronic control device, which is a constituent of the apparatus. The apparatus carries out time-division multiplex transmission of optionally digital and/or analog signals - also mixed together - via three cable conductors using a minimum of components. Modulation and/or encoding and/or A/D conversion and/or D/A conversion of data are all superfluous. High data security is achieved by placing onto the supply voltage of at least one data concentrator a reset pulse, which is immune to interference, and channel selection pulses, which are dependent on the number of channels, and by utilizing at least one transmission channel for the transmission of a reference signal. The reset and channel selection pulses differ from one another in respect of their amplitude. A central electronics unit in the control device to be supplied with data determines which and how many measuring channels are interrogated during a detection cycle, by controlling the time sequence of the channel selection pulses and/or the points in time when the reset pulses are output.

Description

The invention relates to a device for transmission a plurality of signals to an electronic control device as part of the facility according to the genus of claim 1.

A lot of sensors come in modern vehicles, Switches and other electronic devices for Commitment. A large number of connection cables often have to go through the entire vehicle can be relocated and thus increases the Assembly effort and costs. In addition, for each Signal source the corresponding number of connection pins on Control device are provided, which often leads to the fact that the next larger housing is used for a control unit just to accommodate all connections.

DE 33 29 049 C2 describes a data acquisition system, in which several substations via a two-wire over transmission line are connected to a control center. The Power supply to substations and transmitters ge also happens over the two-wire transmission line. The transmission of the message is done by modulation the voltage on the transmission line.  

DE 31 50 313 C2 describes an arrangement for the determination and feedback of the position of a number of switches and for monitoring the connecting line, wherein several reporting points via a collective line to a Zen trale are connected. Special mel dephases for the purpose of function coding impulse difference transmitted duration.

DE 28 43 135 A1 deals with a transmission network for Information where a variety of peripheral Mel to a main office via a manifold connected.

The main disadvantage of the above solutions is that they are complex and therefore expensive because of the data ultimately modulated or encoded in some form Need to become. In addition, each signal source must have a sub be assigned to the station, even if signal sources are close together locally.

DD 2 69 928 A1 describes an arrangement for the time mul Tiplexen transmission of a variety of information security gnalen over a two-wire line, the selection of respective station generating an information signal by means of a microcomputer. This is in everyone Station u. a. a window discriminator available. Here a specific voltage pe for each station gel generated that only one in the switch window ten of the window discriminators of said stations falls. Each of the window discriminators controls an electro switch on via the station in question assigned sensors via a transmitter to the Two-wire line is switched. The measured value is mapped in a current value and then as  Voltage drop across a measuring resistor is detected.

This solution has the disadvantage that, for example small shunts on the two-wire line to wrong Allocate the sensor assignments. Finiteness too of the measuring resistor sets limits in this regard. Also is the maximum signal level swing through the input resistor levels of window discriminators limited.

It is therefore an object of the invention to provide a device for Transmission of a plurality of signals to an electronic cal control unit as part of the facility beat that particularly inexpensive and yet disturbing is insensitive to rungs.

This task is carried out in a generic facility solved with the characterizing features of claim 1.

The device according to the invention has the advantage that it the transmission to a control unit from either digital and / or analog signals - also mixed together - over three cable cores with a minimum of components leaves. The time-multiplexed transmission makes a modula tion and / or coding of data or signals as well superfluous like their A / D and / or D / A conversion.

A high level of data security is achieved by setting up a interference-resistant reset pulse and channel number-dependent channel Dialing impulses on the supply voltage of at least one Data concentrator and the use of at least one Transmission channel for the transmission of a reference signal reached. Reset and channel selection pulses differ from each other in terms of their amplitude. A central one Electronics, in the control unit to be supplied with data, be  agrees by controlling the time sequence of the channel election impulses and / or the times for the output of the Reset impulses, which or how many measuring channels during of an acquisition cycle. The number of Measuring channels is not limited and is only by the maximum permissible cycle time limited.

Because the control signals over the power supply wire over a special control line is superfluous sig, which means not only the wiring effort, but also also the number of connection pins on the central control unit can be minimized. In use cases where a special ground line can be dispensed with and the supply voltage on site from the vehicle mass is available and the latter also as signal return can only be used in this respect only one in total core cable from a signal acquisition location to the control device.

The device according to the invention is in the drawing illustrated and explained below. Show it:

Fig. 1 is a block diagram of the device, which comprises central electronics and, for example, three data concentrators connected there;

Fig. 2 is a schematic block diagram of the data concentrator;

FIG. 3 shows the functional diagram of an exemplary implementation of a Spannungspegeldiskrimina tors;

Fig. 4 shows the block diagram of an exemplary Realization of a control unit;

Figure 5 is a schematic representation of the time course of the supply voltage. Outputted to the data concentrators.

Referring to FIG. 1, the device comprises a central control unit 2 and - in the general case - a plurality of Da tenkonzentratoren 1.1 to 1 .m, which are each connected via a three-pole connection 20.1 .m to 20 to the central control unit 2. The data concentrators 1.1 to 1 .m who the from signal sources 3.1.1 to 3.1. n, 3.2 . until 3.2. n or 3 .m. 1 to 3 mn fed. With regard to the signal paths, the device can therefore have a tree structure.

Fig. 2 shows the basic structure of a data concentrator 1 corresponding to the data concentrators 1.1 to 1.m in Fig. 1. Via a ground line 5 and a supply line 4 , the data concentrator 1 is supplied with power by the control unit 2 . The connecting wire 4 is connected to a device 17 for protection against overvoltage and / or incorrect polarity; the latter can also be connected to the ground wire 5 in United States. The output of 17 is on the one hand led to a device 7 for preferably limiting the amount or regulating the voltage on the supply wire 4 to the operating voltage value for the devices 8 , 9 , 10 and 11.0 to 11. (n + 1) of the data concentrator 1 , and on the other hand to the input of a voltage level discriminator 8 . The latter has a counting pulse output and a reset output 15 and 16, respectively. These are connected to corresponding inputs of a binary counter 9 with (n + 2) output states, which in turn controls a 1-off (n + 2) decoder 10 .

Each of the (n + 2) outputs of the decoder 10 controls one of (n + 2) electronic or electromechanical switches 11.0 to 11. (n + 1). There are n signal sources 3.1 to 3. n and, for example, two reference resistors or reference signal sources 12 and 13 , which are connected to one of their two connections 19.0 to 19 . (n + 1) e.g. B. to ground 5 . The other connections 18.0 to 18 . (n + 1) of the signal sources 3.1 to 3. n and reference resistors or reference signal sources 12 and 13 are respectively connected to the switching paths 11.0 to 11. (n + 1). The other switching section connections of the switches 11.0 to 11 (n + 1) are connected to the signal wire 6 , which is connected to the central control unit 2 .

Fig. 3 illustrates a possible implementation of the Spannungspegeldiskriminators. 8 Input resistors 21 , 22 and 23 connected in series form a voltage divider with two taps. The input of a first Schmitt trigger 24 is connected to the high tap between the resistors 21 and 22 , the latter - depending on the type of counter 9 below - a delay gate 26 can be connected downstream. At the deep tap between the resistors 22 and 23 , the input of a second Schmitt trigger 25 is connected, the latter - depending on the type of counter 9 below - a delay gate 27 can be connected downstream.

Fig. 4 illustrates an exemplary electronic control unit 2. It includes conventional GND connected to ground and polarity reversal and overvoltage protection means 33 supplied by the on-board power rail 32 with the on-board voltage U _B as well as pulse generating means 34 , the residual pulses 28 with a preferably larger amplitude U _r and counting or stepping pulses 29 with a preferably smaller one Generate at plitude U _z . Furthermore, the control unit 2 comprises further means 35 for additively linking the aforementioned pulses 28 and 29 with the filter 33 provided in the control unit 2 for the supply of signal transmitters by the means 33 and essentially constant supply voltage U _b . The means 35 are accordingly in connection with the means 33 and 34 and emit a supply voltage U _V for data concentrators 1 and 1.1 to 1 .m, as illustrated in FIG. 5.

Without restricting the generality, the means 34 , 35 , 36 and 37 can be partially, largely or completely implemented by a μ-computer or μ-controller, not shown in the figures.

With 37 the core of the control unit is designated as part of the device. On the one hand, it is operatively connected to the means 34 . With regard to its function, it can be such. B. to act as a control device for an air conditioning system, for a brake monitoring device or the like.

The control device 37 receives the signals transmitted through the transmission wires 5 and 6 according to FIG. 2 or 5.1 to 5 .m and 6.1 to 6 .m via interference-suppressing input means 36 . B. sensors or switches and forwards the respective current signal to the control device 37 .

The pulse generation by the means 34 and the reading of signals in the control device 37 or z. B. with means of one of the means 36 with comprised A / D converter happens either rigidly or with a certain permissible conditions fluctuation in time within the current channel acquisition phase, so z. B. in Implementation tion of the means 34 , 35 , 36 and 37 by a µ-Control ler, which also performs the signal processing in addition to the signal recovery.

The control means 37 can nevertheless have individual inputs and / or outputs 38 , for example for controlling actuators or warning and / or diagnostic means, as well as a bus connection 40 , for example to a CAN bus, not shown here in the figures. In the latter case in particular, the means 37 can include, or essentially a bus controller 39 , for example a CAN chip, or implement the function of such a bus controller. The entire control function of the control unit 2 can in this case be exhausted in the pure sequence control of the signal collection from sensors or the sensor selection depending on current signal requirements from the bus, ie, a communication function instead of the usual activation of units. The wires 4.1 to 4 .m, 5.1 to 5 .m and 6.1 to 6 .m of the lines 20.1 , 20.2 to 20 .m are with the outputs and inputs of the aforementioned means 35 and 33 and 36 via three distribution rails 4 ' , 5 'and 6 ' connected, where 5 'is, for example, the signal reference ground.

The overall function of the device will now be explained with reference to FIG. 5, the latter illustrating the time course of the supply voltage U _V between the wires 4 and 5 output by the control device 2 .

If no or only a certain measured value or sensor or a reference resistor or channel are read by the control unit for a long time, the Da tenkonzentrator 1 is at rest. The control unit 2 only outputs the idle operating voltage U _b between the wires 4 and 5 to the data concentrator for as long. As a result, the counter reading of the counter 9 is and remains constant, and the current signal transmitter remains connected to the wire 6 .

If different measured values or several sensors are to be queried, the means 35 set in the control unit 2 to the supply voltage U _{b obtained} from the means 33 , essentially constant supply voltage U _b in the sense of an addition, said reset pulses 28 with the amplitude U _r up to the roof amplitude U _R and lower counting pulses 29 with the amplitude U _z up to the lower roof amplitude U _Z.

The device 17 in the data concentrator 1 protects ben ben z. B. against incorrect polarity and / or damagingly high load dump voltage peaks, as z. B. zen can occur in vehicle on-board. However, it lets the supply voltage U _V with the time course according to FIG. 5 unimpeded to the input of the voltage level discriminator 8 - implemented in a playful manner according to FIG. 3 - lastly acts as follows.

When the signals at their inputs exceed or fall below their specific switch-on and switch-off threshold voltages, the Schmitt triggers 24 and 25 generate steep-edged signal transitions at their outputs, which in this way form pulses that are used to drive the counter 9 own.

The differently high count and reset pulses 28 and 29 are evaluated by the Schmitt trigger 24 in such a way that both pulses - after the first voltage division by the resistors 21 and ( 22 + 23 ) - are still greater than the response threshold of the Schmitt trigger 24th , while the Schmitt trigger 25 only evaluates the reset pulses by virtue of the larger second partial voltage ratio of the resistors ( 21 + 22 ) and 23 only the higher reset pulses cause the response threshold of the Schmitt trigger 25 to be exceeded.

The pulses 30 thus occurring at the output 15 of the Schmitt trigger 24 act on the counter input "C" of the counter 9 in the sense of advancing the same. The pulses 31 occurring at the output 16 of the Schmitt trigger 25 act on the reset input "R" of the counter 9 in the sense of resetting it to a defined output count, for example thus to "00000". It is ersicht Lich that the pending pulses 30 at output 15 correspond both with counting and reset pulses 28 and 29 and the pending pulses 31 at output 16 only with reset pulses 28 .

If the counter 9 is therefore a counter with a dominant reset, the counter is reset when a pulse 31 occurs at the reset input “R”, even if a pulse 30 is present at the input “C” for further counting.

If the counter 9, on the other hand, is a counter with a different reset characteristic, the Schmitt triggers 24 and 25 are selected by suitable selection of the response thresholds depending on the edge steepness of the pulses 28 and 29 and / or an optional, delaying gate 26 or 27 a small time offset of the pulses 30 and 31 causes each other. The resulting ease of newspaper enables either an immediate reset during the counting increment or a quasi-dominant reset holding a counter 9 not dominating the reset.

Each measuring cycle is started by the control unit 2 with a reset pulse 28 , and the counting pulses 29 are then output in succession in accordance with the sensors currently to be queried. The decoder 10 sets the current counter reading in control commands to only one of the switches 11.0 to 11 . (n + 1), so that according to the counting pulse sequence the switch 11.0 successively the reference resistor or the reference signal source 12 , the switch 11.1 the signal source 3.1 , the switch 11.2 the signal source 3.2 etc. and finally the switch 11. (n + 1) the Reference resistor or the reference signal source 13 switches between the ground wire 5 and the signal wire 6 .

By resetting the counter 9 at the beginning of each measuring cycle to the defined initial state, the reference resistor or the reference signal source 12 is switched between the signal and ground wires 6 and 5 during the measuring phase M0. This resistor or signal source preferably has a value or output signal which lies outside the normally detectable value range of all other signal sources 3.1 to 3. n. The control unit 2 can determine the freedom from errors of the transmission path by comparing the detectable value with a tolerance window stored in the control unit or, if there is an error, suppress the device, for example, the signal source 3.1 and following.

Without restricting generality, a reference resistor 13 may also not be connected to ground, but may, for example, be connected to the output of controller 7 . The control unit 2 can then measure the correctness of the operating voltage for the parts 8 , 9 , 10 and 11.0 to 11 (n + 1) by means of such a comparatively low resistance 13 with high resistance, and the resistance of the ground line 5 via the same resistance 13 with low resistance check connection 20 .

The control unit 2 can place the triangles marked in FIG. 4, following reset or advance pulses at the start of reading the respective signals, either according to a fixed time grid between the counts 29 or place them, depending on the load that then no exact time measured between the reset and index pulses and the subsequent acquisition times will be complied with.

If individual channels are to be skipped, the control unit 2 outputs the advance pulses 29 to the advance pulse in the channel in which measurement is to be carried out with the highest possible repetition frequency (ie as a burst), since then the parasitic oscillation processes on the decay will not subside Signal line between aufeinan the following counts must be waited for, as z. B. is required for the transmission of analog measured values.

Conversely, the control unit can be different or Delay or hide the next one for any length of time Count the continuous data reception from a certain signal source as long as required received, such as when a signal value is one for a danger situation has exceeded the indicative limit and therefore it should be recorded with current priority.  

The last advance pulse of the cycle switches via the switch 11. (N + 1) the second reference resistor or signal source 13 to the signal wire 6 , which - by suitable dimensioning of 13 - also assumes a signal value which is outside the Range of normally possible values is from the other signal sources.

The central control unit 2 can thus determine on the basis of this value that all measuring phases M1 to Mn of the cycle have been selected and have been successfully exited. In addition, the control unit can also perform a plausibility check as to whether the corresponding reference value of the reference resistor (s) or signal source 13 is actually received after a predetermined number of switching pulses.

In the example shown, the supply ground line 5 also serves as a signal ground line, which is always possible if the internal power consumption of the data concentrator is low. This is the case when it is implemented in CMOS technology.

The device is not subject to any restrictions with regard to the connectable signal sources, as long as only the controlled switches 11.0 to 11 (n + 1) are adapted to the characteristics to be transmitted in terms of the characteristics of their switching paths, that is to say, for. B. their ON resistance in relation to the low impedance of a sensor to be connected. To this extent come as signal sources switches, analog sensors, serial output ports of sensors with z. B. digital signal preprocessing etc. in question.

The scope of the invention is not left if such a device with a corresponding control unit 2 is also provided in a vehicle, for example within a bus network. In the context of such an application, the control unit 2 can contain a CAN controller or protocoll chip for coupling to a CAN bus, for example, and the control functions of the control unit 2 - apart from control functions for handling communication via such a bus - the selection of sensor channels described above may be restricted, so that it is only effective as a communication control unit.

Claims (10)

1. A device for transmitting a plurality of signals to an electronic control unit as part of the device, the device signal generator on the part comprises a plurality of switching devices for individual connection individual from a plurality of signal transmitters to a two-pole signal path, characterized in that the control device ( 2 ) includes:

• - Means for generating and providing reset pulses ( 28 ) with a first defined amplitude (U _r ) and counting or advancing pulses ( 29 ) with a second defined amplitude (U _z ), the first amplitude being larger as the second amplitude;
• - Means for additive linking ( 35 ) of the aforementioned pulses ( 28 , 29 ) with a substantially constant supply voltage (U.) Derived in the control device for the purpose of supplying signal generator -side means ( 8 , 9 , 10 , 11.0-11. (N + 1)) _b ) and for the transmission of the resulting supply voltage (U _V );
• - Means for receiving ( 36 ) and for periodically detecting and assigning ( 37 ) the signals that can be received via said two-pole signal path ( 5 , 6 ; 5.1. , 6.1 , 5.2 , 6.2 , etc .; 5 ', 6 ') ;
• - Means for controlling ( 37 ) the means for generating ( 34 ) reset ( 28 ) and counting or advancing pulses ( 29 ) and for receiving ( 36 ), for assigning signals and signal transmitters ( 37 ) and for with the aforementioned pulses ( 28 , 29 ) time-chained acquisition and evaluation ( 37 ) of said signals, and
• - That said plurality of switching devices ( 11.1 , 11.1 to 11. n) for individual connection of individual from a plurality (n) of signal generator / s ( 3.1 to 3 .n) to a two-pole signal path ( 5 , 6 ) components of a remote data concentrator ( 1 ), which further comprises:
• - Amplitude discrimination means ( 8 ), to which the supply voltage (U _V ) prepared in the control unit ( 2 ) can be fed and which separates and separates the differently high pulses ( 28 , 29 ) in the supply voltage into reset ( 31 ) and counting pulses ( 30 ) 15, 16 ) provide;
• - Counting means ( 9 ) which can be acted upon by ( 15, 16 ) the amplitude discriminating means ( 8 ) both with separate reset pulses ( 31 ) for zeroing and with other pulses ( 30 ) for incrementing the count;
• - From the counting means ( 9 ) controllable Decodiermit tel ( 10 ), from the outputs of which the plurality of switching devices ( 11.1 to 11. n) can be individually controlled;
• - A plurality (n) of paired connections ( 18.1 , 19.1 ; 18.2 , 19.2 to 18. n, 19. n) for a corresponding plurality (n) of signal generators ( 3.1 , 1.2 to 3. n), via which only one Signal transmitter (e.g. 3.3 from 3.1 to 3 .n.) Can be switched to the two-pole signal path ( 6 , 5 ) via the correspondingly controlled switching device (e.g. 11.3 from 11.1 to 11 .n),
• - So that the selection of the signal generator ( 3.1 to 3. n.) and the power supply of the aforementioned signal generator-side means ( 8 , 9 , 10 , 11.1 to 11. n) in a circuit ( 4 , 5 ), which is the circuit of the Signal transmission ( 6 , 5 ) is decoupled.

2. Device according to claim 1, characterized in

• - That the decoding means ( 10 ) have at least one further output for controlling at least one additional Lich existing switching device ( 11.0 , 11. (n + 1), via which instead of signal transmitters ( 3.1 to 3. n) at least one reference resistor or one Reference signal source ( 12 , 13 ) can be connected to the two-pole signal path ( 6 , 5 ).

3. Device according to claim 1, characterized in

• - That of the means for control ( 37 ) by influencing the time sequence of the counting or advancing pulses ( 29 ) and the times for the delivery of reset pulses ( 28 ) which during a detection cycle between two reset pulses ( 28th ) each of the signal channels currently to be transmitted can be selected.

4. Device according to claim 3, characterized in

• - That at least the means for generating reset pulses ( 28 ) and counting or advancing pulses ( 29 ), the means for receiving ( 36 ) and for periodically detecting and assigning signals and signal transmitters ( 37 ) and the means for With the aforementioned pulses ( 28 , 29 ), time-linked acquisition and evaluation ( 37 ) of said signals are implemented essentially by software in a microcontroller.

5. Device according to claim 1, characterized in

• - That the times of detection ( 37 ) of signals len between two counts or forward pulses are variable.

6. Device according to claim 1, characterized in

• - That the counting or advancing pulses ( 29 ) follow one another in time so that there are specific lengths for different signal transmitters that relate to the detection phases.

7. Device according to claim 1, characterized in

• - That the counting or indexing pulses ( 29 ) have freely variable following intervals.

8. Device according to claim 1, characterized in

• - That in the case of signaling devices or channels to be skipped, the counting or advancing pulses ( 29 ) can be applied in a uniformly short sequence until the counting means ( 9 ) have reached a counter reading which corresponds to the next signaling device to be queried.

9. Device according to claim 2, characterized in

• - That the means for generating reset ( 28 ) and counting or stepping pulses ( 29 ) whose sequence according to an analysis of the at least one reference resistor or the at least one reference signal source ( 12 , 13 ) via the two-pole signal path ( 6 , 5 ) change received signal values.

10. Device according to claim 1, characterized in

• - That the data concentrator ( 1 ) of the further means ( 7 ) for delivering one of the pulses ( 28 , 29 ) free operating voltage for the power-consuming means ( 8 , 9 , 10 , 11.1 to 11. n) of the data concentrator ( 1 ) .