EP0860762A2 - Circuit and method for generating a DC output voltage - Google Patents

Abstract

The output voltage ÄUzÜ is generated based upon a variable input voltage ÄUbattÜ. After an initial period the voltage is held at a constant value ÄUnennÜ until a specific voltage reduction has been obtained Ä(U2Ü relative to the input voltage. The voltage control is provided by a regulating stage coupled to a switching circuit.

Description

The invention relates to a circuit arrangement for generating a DC supply voltage as a function of an input DC voltage according to the preamble of claim 1 and a Method for generating a DC supply voltage for a signal generator unit according to claim 7.

Such circuit arrangements are used to e.g. Sensors with downstream signaling unit with a voltage that is designed so that fluctuations in the DC input voltage Functionality of the unit to be supplied is not endangered. It has The voltage difference with which the Supply voltage for the consumer below the input voltage is, as shown in Figure 1, up to a first value of the input voltage to keep to a first, constant value and from one certain value of the input voltage to a second larger value to keep constant. In the intermediate transition area, in Normal operation, the supply voltage remains constant and is regardless of the input voltage.

Such a circuit arrangement is the patent DE 25 33 199 C3 remove. This circuit arrangement produces the course described the supply voltage depending on the input voltage a complex transistor circuit, the implementation of which is complex and expensive considerable costs.

In addition, DE 41 31 170 A teaches a device in which means a Zener diode (Z diode) and a comparator and a controllable Current source a supply voltage is generated, which is in Intervals changes depending on the input voltage. This arrangement also proves due to its complexity, especially the controllable power source, as too complex and expensive.

Furthermore, further circuit arrangements are available in the prior art Voltage stabilization with a Z-diode known (compare Tietze / Schenk: Semiconductor circuit technology, 10th edition 1993, page 555 ff.).

From the prior art mentioned above are also methods for Generate such a DC supply voltage.

The supply voltage is a non-constant DC input voltage, for example a battery, won and for the Signaling unit provided. The signal transmission from the signal generator unit to an evaluation circuit is carried out by the supply voltage Imprinted current pulses for the signaling unit required DC supply voltage is preferably set to one kept constant nominal amount, which is a safe signal transmission and signal recognition guaranteed and also for the signal generator unit downstream circuit elements, for example sensors, is required.

A preferred area of application for such methods is the coupling of decentralized sensor systems with central control electronics in motor vehicles, where the outsourced sensors and the associated signal generator units no longer directly from the vehicle electrical system voltage, but instead indirectly supplied by the central control unit using a current interface will. The changes in current are made by the central control unit of the power supply line to the outsourced signal generator unit.

Because of the ohmic and capacitive components of the sensor and signal generator unit as well as the electrical lines, every voltage change affects in the central control unit as a current change that the imposed current impulses. The signal evaluation is therefore special susceptible to supply voltage fluctuations.

The object of the invention is to produce a circuit arrangement specify a DC supply voltage with that described above DC supply voltage curve as a function of the DC input voltage can be achieved in a simple manner. The task is furthermore, a method for generating a DC supply voltage to show for a signaling unit in which fluctuations in DC input voltage largely does not transmit the current signal hinder.

The task is through the features of claim 1 for the Circuit arrangement and solved by claim 7 for the method.

The circuit arrangement generates the desired profile of the DC supply voltage depending on the input DC voltage by means of a surprisingly simple circuit arrangement based on two zener diode arrays. Advantageous developments of the invention are described in claims 2 to 6. These describe in particular the dimensioning of the individual components. The control loop tracking according to claim 5 enables a non-reactive Current decoupling of the circuit arrangement.

This is so advantageous and simple in this circuit arrangement implemented feedback-free tracking of the supply voltage for a method for generating a DC supply voltage for a Signaling unit can be used extremely advantageously.

There will be several depending on the input DC voltage Intervals a DC supply voltage is provided, which over a Control circuit the DC supply voltage at the connection to the signal generator unit tracks the generated DC supply voltage without retroactive effect. Three connected input voltage intervals are preferred distinguished. In a first voltage interval the DC supply voltage of the input DC voltage is increased by one constant first amount reduced tracking, resulting in an emergency operation the signaling unit is guaranteed and also the Evaluation circuit can evaluate the signals of the signal generator unit, too if these are reduced. In a subsequent second Voltage interval becomes the supply voltage with a constant nominal amount provided. This means that voltage compensation takes place for the normal operating state. However, if the DC input voltage exceeds this second voltage interval, follows DC supply voltage reduced by a second constant amount the input DC voltage. The inventive solution also ensures outside the compensated voltage range in normal operation defined states on the signaling unit and thus a the best possible maintenance of the operation of the signaling unit and the evaluation circuit, for example in the event of input voltage fluctuations. This Methods so advantageous for signal transmission by means of the signal stream can be extremely simple and effective through the circuit arrangement Realize according to one of claims 1 to 5, and in principle also other circuit arrangements, such as from the not yet disclosed Patent application DE 196 07 802 (EP 0 793 159) for generating the three Voltage intervals can be used. This circuitry then need to proceed according to the characteristics of claim 7 in the control loop, the output voltage at the connection to the signal generator unit (Sat) of the generated DC supply voltage tracks and ensures freedom of feedback.

Figur 1:

die Versorgungsspannung in Abhängigkeit der anliegenden Eingangsgleichspannung,

Figur 2

ein Blockschaltbild des Verfahrens,

Figur 3

Blockschaltbild der Gesamtanordnung aus der Schaltungsanordnung zum Erzeugen der Versorgungsgleichspannung, dem Regelkreis, der Signalgebereinheit und der zugeordneten Auswerteschaltung

Figur 4a

Stromimpulse der Signalgebereinheit

Figur 4b

Spannung an der Signalgebereinheit

Figur 4c

Ausgangspegel der Auswerteschaltung

Figur 4d

Basisstrom des Längstransistors im Regelkreis

Figur 5

Detailansicht der Schaltungsanordnung zum Erzeugen der Versorgungsgleichspannung aus der Eingangsgleichspannung

The invention is explained in more detail below on the basis of exemplary embodiments and figures. It shows:

Figure 1:

the supply voltage depending on the applied DC input voltage,

Figure 2

a block diagram of the method,

Figure 3

Block diagram of the overall arrangement from the circuit arrangement for generating the DC supply voltage, the control circuit, the signal generator unit and the associated evaluation circuit

Figure 4a

Current pulses from the signal generator unit

Figure 4b

Voltage at the signal generator unit

Figure 4c

Output level of the evaluation circuit

Figure 4d

Base current of the series transistor in the control loop

Figure 5

Detailed view of the circuit arrangement for generating the DC supply voltage from the DC input voltage

FIG. 1 shows the three voltage _intervals I ₁ , I ₂ , I _{3 of} the input _DC voltage U _batt and the assigned supply voltage U _{out on the} output side. As can be seen in the first interval I ₁ , the _DC supply voltage of the input _DC voltage U _batt is tracked reduced by a constant first amount ΔU ₁ in this area. In the interval _I2, the normal mode, the supply voltage U _out is maintained at the desired nominal voltage _Unom. However, if the input voltage U _{batt exceeds} this second voltage _interval I ₂ , an output voltage U _{out is} generated in the voltage _interval I ₃ , which follows the input voltage U _batt reduced by a second constant amount ΔU ₂ . The possible circuitry implementation is explained in more detail in connection with FIGS. 3 and 5.

Figure 2 now shows a block diagram of the method. The input _DC voltage U _batt can fluctuate beyond the limits of the interval I1, for example in the case of a battery due to temperature influences or other load elements. The circuit arrangement 1, as sketched in FIG. 1, first generates the DC supply voltage U _z from the DC input voltage, while the control circuit 2 produces the output voltage U _out at the connection to the unit to be supplied (for example a signal transmitter unit (Sat), see exemplary embodiment according to FIG 3) the DC supply voltage U _z generated by the circuit arrangement 1 leads to.

The current pulses I _signal generated by the signal transmitter unit Sat in the exemplary embodiment explained in more detail in FIG. 3 do not lead to fluctuations in the applied output voltage U _out , since the interposed control circuit 2 immediately compensates for this, without having any effect on the circuit arrangement 1.

• Schaltungsanordnung zum Erzeugen der Versorgungsgleichspannung 1,
• dem Regelkreis 2
• der Signalgebereinheit Sat und
• der zugeordneten Auswerteschaltung (I_mess).

FIG. 3 shows a block diagram of the overall arrangement from:

• Circuit arrangement for generating the DC supply voltage 1,
• the control loop 2
• the signaling unit Sat and
• the assigned evaluation circuit (I _mess ).

Since the circuit arrangement for generating the DC supply voltage 1 in FIG. 5 is shown again in detail, this part for both figures be described together.

Figures 3 and 5 show the input with the non-compensated, non-constant input DC voltage U _Batt , for example a connection to a car battery. Starting from the input _DC voltage U _Batt, there is a first current path I ₁ and a second current path I ₂ parallel to it. In I ₁ , a number n of diodes D ₁ ... D _{n connected} in series are arranged poled in the forward direction, the number n of diodes D determining the first constant amount ΔU ₁ . In order to ensure a voltage drop across the diodes D ₁ ... D _n , these are connected to ground via a first resistor R ₁ , so that a diode current is created which is so large that the diodes D ₁ ... D _n in the Passband can be controlled. On the other hand, the last diode (in FIG. 3 D ₂ , in FIG. 5 D _n ) is connected to the output of the DC supply voltage U _z via a second, high-resistance resistor R ₂ . Parallel to the arrangement in the first current path I ₁ there is a current path I _{2 which} , starting from the input _DC voltage U _{Batt, has} a Zener diode Z ₁ towards the output U _z . Furthermore, the output of the DC supply voltage U _{z is} connected to ground via a third resistor R ₃ and a second Z-diode arrangement Z ₂ in series therewith.

The course of the DC supply voltage U _z already shown in FIG. 1 results in terms of circuitry as shown below:

In the first voltage interval I ₁ the input DC voltage U _Batt the Zener voltage of the Z ₂ is the DC supply voltage U _z is reduced by the voltage drop U _D via the diodes D ₁ ... D _n constant for the input DC voltage U _Batt tracked until reaching. If the input _DC voltage U _Batt now _exceeds the value of Z ₂ , the second Zener diode Z ₂ becomes conductive. The current through the diodes D ₁ ... D _n can thus flow to ground both via the resistor R ₁ and in parallel to it through the series arrangement of R ₂ , R ₃ and Z ₂ . A voltage divider is formed from the resistors R ₂ and R ₃ , with R _{2 being} chosen to be higher by a factor of 100 than R ₃ by a factor of 100, so that a change in voltage of the input _DC voltage U _Batt is smaller by a factor of 100 and is therefore not detectable by D _1. .D _n works. Compensation for the DC input voltage changes, e.g. the battery voltage fluctuations, is achieved. However, if the input _DC voltage U _{Batt exceeds} a value which is around UZ ₂ plus UZ ₁ , the first Zener diode Z ₁ in the second current path I ₂ also becomes conductive. This bridges the diodes and the resistor R ₂ . The voltage divider between R ₂ and R ₃ is eliminated. The DC supply voltage U _z now follows in a second constant amount ΔU _{2 of} the input DC voltage U _Batt , the second amount ΔU _{2 being} largely determined by the voltage UZ ₁ . The Zener diode arrangements Z ₁ and Z ₂ can be implemented both simple Z diodes and temperature compensated Zener diode arrangements, for example by connecting them in series with temperature compensating diodes with correspondingly different temperature coefficients. The desired dependency of the _DC supply voltage U _z on the applied _DC input voltage U _{batt arises} . Of course, this embodiment of the circuit arrangement according to FIG. 5 can also be used advantageously for other uses than that shown in FIG. 3, that is to say without a signal transmitter unit for current signaling and an associated evaluation circuit or the control circuit 2, due to its simplicity.

Now consider the circuit arrangement discussed 1 shows the overall arrangement according to FIG. 3, this shows the preferred use the circuit arrangement for the voltage supply of a signal generator unit Sat, which is controlled via a control circuit 2. Instead of the particularly preferred embodiment of the circuit arrangement 5 could in principle also be another suitable one Circuit arrangement, for example in DE 196 07 802 (EP 0 793 159) described, can be arranged before the control loop 2, the design 5 already described Has advantages.

Regardless of the configuration of the circuit arrangement 1, the control circuit 2 compares the output voltage U _out with the DC supply voltage U _{z present} on the input side. The signal transmitter unit Sat has a closed-circuit current path I _R and a signal current path I _signal . As is known, this can be achieved, for example, by switchable signal loads. On the input side, the evaluation circuit I _{mess is} arranged between the control circuit 2 and the recompensated input of the circuit _arrangement 1 which is at U _batt and is formed via a current mirror, formed from the transistors T ₂ and T ₃ , as well as the resistors RM ₁ and RM ₂ and a constant current _source the signal sent by the transmitter unit satellite signal current I evaluates _signal by a comparator K ₂ compares the voltage drops across the resistors RM ₁ and RM ₂ and the output signal S passes to further processing, for example to a microprocessor. The control circuit 2 is formed from a comparator K ₁ , at the output of which there is the resistor R _K and the transistor T _K , the transistor T _{K being connected} as a series transistor with the base to the comparator K ₁ and with the emitter to the signaling unit Sat. The DC supply voltage U _z generated by the circuit arrangement 1 is compared in the comparator K ₁ with U _out and U _{out is readjusted} accordingly.

The current pulses I _signal in the amount of 40 mA for signal transmission, which are considerable in this exemplary embodiment, act, decoupled by the control circuit 2, not on the supply voltage-generating circuit arrangement 1. The current pulses I _signal are conducted quasi unaffected by the transistor TK to the current measuring evaluation circuit I _mess and recognized there. The voltage across the evaluation circuit I _mess is the difference between the DC input voltage U _Batt and the output voltage U _out at the signal generator unit Sat and the voltage drop across the transistor TK. The difference is limited by the method used and is therefore approximately between the amounts ΔU ₁ and ΔU ₂ . The functioning of the evaluation circuit I _measurement is thus ensured by the circuit 1 and the control circuit 2, even if the DC input voltage U _Batt strongly deviates from the desired nominal voltage _Unom.

FIG. 4 shows the functional curves of characteristic quantities in the circuit arrangement shown in FIG. 3. Figure 4a shows the current pulses I _signal plus the constant quiescent current I _r . Diagram 4b shows the output voltage U _out at the signal transmitter unit Sat. The output voltage U _out has extremely short excursions in the edge moments of the signal current I _signal , but is immediately returned to the set operating point by the control circuit 2 by the base current in control circuit 2 responding ( see Fig. 4d). The signal arrives unadulterated at the output S of the evaluation circuit I _mess (cf. FIG. 4c).

Claims (8)

Circuit arrangement for generating a _DC supply voltage (U _z ) at an output as a function of a non-constant input _DC voltage (U _batt ) present on the input side, i1) in which the input _DC voltage (U _Batt ) is transmitted reduced by a constant first amount (ΔU ₁ ) in a first voltage interval (I ₁ ), i2) in a subsequent second voltage interval (I ₂₎ the DC supply voltage (U _z) is constant (U _nominal) is held and, i3) if the DC input voltage (U _Batt) exceeds this second voltage interval (I _{2), 2)} the input DC voltage (U _Batt) follows the output-side DC supply voltage (U _z) to a second constant value (.DELTA.U,
characterized in that a) starting from the input _DC voltage (U _Batt ) in a first current path, polarized in the forward direction, there are a number (n) of series-connected diodes (D ₁ ... D _n ), which on the one hand have a first resistor (R ₁ ) to ground and on the other hand, are connected to the output of the DC supply voltage (U _z ) via a second, high-resistance resistor (R ₂ ), b) a second current path is connected in parallel with the first current path from the DC input voltage (U _Batt ) via a first Zener diode arrangement (Z ₁ ) to the output and c) the output of the DC supply voltage (U _z ) is connected to ground via a third resistor (R ₃ ) and in series with a second Zener diode arrangement (Z ₂ ). Circuit arrangement according to Claim 1, characterized in that the first amount (ΔU ₁ ) of the reduction of the output voltage compared to the input DC voltage (U _Batt ) is determined by the number of diodes and the Zener voltages of the first and second Zener diode arrangement (Z ₁ , Z ₂ ) . Circuit arrangement according to Claim 1, characterized in that the Zener voltage of the second Zener diode arrangement (Z ₂ ) determines the limit between the first and second voltage interval (I ₁ / I ₂ ). Circuit arrangement according to Claim 1, characterized in that the Zener voltage of the first Zener diode arrangement (Z ₁ ) is greater than the Zener voltage of the second Zener diode arrangement (Z ₂ ) and determines the upper limit of the second voltage interval (I ₂ ). Circuit arrangement according to one of the preceding claims, characterized in that a control circuit (2) is added to the output of the circuit arrangement (1) towards the unit (SAT) to be supplied, in such a way that the output voltage (U _out ) generated by the control circuit (2) ) for the unit to be supplied (SAT) the supply voltage (U _z ) is tracked. Use of the circuit arrangement according to one of the preceding Claims for the supply of sensor units in motor vehicles. For generating an output voltage (U _out) for a signal generator unit (Sat) at which the output voltage obtained (U _out) from a non-constant input DC voltage (U _Batt) and for the switch unit (Sat), preferably with a constant nominal value (U _nom) Method provided,
the signal transmitter unit (Sat) transmits current pulses (I _signal ) signals impressed by the output voltage (U _out ) to an evaluation circuit (I _mess ), wherein i) a DC supply voltage (U _z ) depending on the input _DC voltage (U _Batt ) is preferably provided differently in preferably three connected input voltage intervals (I ₁ , I ₂ , I ₃ ) such that is transmitted reduced i1) the input DC voltage (U _Batt) in a first voltage interval (I ₁₎ by a constant first amount (.DELTA.U ₁₎ i2) _call in a subsequent second voltage interval (I ₂₎ the DC supply voltage (U _z) with a constant nominal value (U) provides and, i3) if the input voltage (U _Batt ) exceeds this second voltage interval (I ₂ ), DC supply voltage (U _z ) reduced by a second constant amount (ΔU ₂ ) follows the input voltage, and b) a control circuit (2) tracks the output voltage (U _out ) at the output to the signal generator unit (Sat) of the generated DC supply voltage (U _z ). Method according to Claim 7, characterized in that a circuit arrangement (1) according to one of the preceding Claims 1 to 5 is used to generate the DC supply voltage (U _z ).

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