DE10158113B4 - Multivibrator with a comparator - Google Patents

Abstract

Multivibrator with a comparator (K), a capacitor (C), a current source, a reference voltage source and a plurality of switches (S1, ..., S8), characterized in that the switches (S1, ..., S8) so in the Multivibrator lie and can be controlled by the output signal of the comparator (K) that first alternately the reference voltage source with one input (P) of the comparator (K), an electrode (V1) of the capacitor (C) with the current source and the second Input (N) of the comparator (K) and the other electrode (V2) of the capacitor (C) with a discharge potential and then the reference voltage source with the second input (N) of the comparator (K), the other electrode (V2) of the capacitor ( C) with the current source and the first input (P) of the comparator (K) and the first electrode (V1) of the capacitor (C) are connected to the discharge potential.

Description

The invention relates to a multivibrator with a comparator, a capacitor, a current source, one Reference voltage source, and several switches. This circuit is also called oscillator circuit in the following. Furthermore concerns the invention a method for operating a multivibrator.

Such oscillator circuits are Often used in integrated circuits, logic circuits at low frequency, i.e. e.g. to clock in the range of 10 kHz or delay times, e.g. for watchdog timers (Time monitoring) circuits, which can range from milliseconds to a few seconds produce.

An oscillator circuit with two capacitors is known, which are alternately charged and discharged. Such an oscillator circuit is in the 1 shown. One electrode each of the two capacitors C1 and C2 can be connected to a current source Io via the switches S1 and S2. The other electrode of the two capacitors C1 and C2 is grounded. A switch S3 is also connected in parallel with the capacitor C1 and a switch S4 is connected in parallel with the capacitor C2. The electrodes of the capacitors C1 and C2 connected to the current source can additionally be connected via switches S5 and S6 to a first input of a comparator K, the second input of which is supplied with a reference voltage Vref. The output signal of the comparator K is fed to a flip-flop, which generates the clock signal CLK. The flip-flop output signals T2 (= CLK; clock signal) and T1 (T1 = T2 ), which are led to the control inputs of the controllable switches S1, S4 and S5 or S2, S3 and S6, control the controllable switches S1, ..., S6 in such a way that either the switches S1, S4 and S5 or the switches alternate S2, S3 and S6 are closed. If the switches S1, S4 and S5 are closed, the capacitor C1 is charged and the voltage across it is compared with the reference voltage Vref. When the voltage Vref is reached, switches S1, S4 and S5 are opened and switches S2, S3 and S6 are closed. As the capacitor C1 discharges, the capacitor C2 is now charged and its voltage compared with the reference voltage. The cycle period T results from: T = CtotVref / Io , where Ctot denotes the sum of the capacitances of the two capacitors C1 and C2, Vref the reference voltage and Io the current.

The longer the delay times or the lower the frequencies are by an oscillator circuit of the type mentioned above should be achieved, the larger the values for the resistance R and the capacitance C of the oscillator circuit. In most cases, R and C are decisive Measure the silicon chip area consumed by the oscillator circuit. Out Cost and space reasons but it is desirable to contribute to the consumption of silicon chip area to keep the manufacture of integrated circuits as low as possible.

An oscillator circuit of the type mentioned at the beginning, which uses only one capacitor, is from the DE 695 14 090 T2 known. This circuit also contains a first current source with a first current intensity and a second current source with a second current intensity, the current sources having opposite current directions. A first electrode of the capacitor is alternately connected to the first and to the second current source by means of a first and a second switch, so that the capacitor is alternately charged and discharged. The other electrode of the capacitor is grounded. The voltage applied to the capacitor is compared by means of a first comparator with an upper threshold value, which is supplied by a first reference voltage source, and by means of a second comparator, with a lower threshold value, which is supplied by a second reference voltage source. The outputs of the two comparators are alternately connected to the input of an inverter, which supplies the output signal of the circuit, by means of a third and a fourth switch. This output signal is also used to control the switches.

The invention has for its object to provide a further oscillator circuit, in particular in an integrated form compared to known circuits, the structure of which in 1 shown circuit correspond, is much more compact. The invention is also based on the object of providing a further method for operating an oscillator circuit.

According to the invention, this object is achieved by a multivibrator mentioned at the outset, in which the switches are located in the multivibrator and can be controlled by the output signal of the comparator in such a way that first alternately the reference voltage source with one input of the comparator, one electrode of the capacitor with the current source and the second input of the comparator and the other electrode of the capacitor with a discharge potential and then the reference voltage source with the second input of the comparator, the other electrode of the capacitor with the current source and the first input of the comparator and the first electrode of the capacitor are connected to the discharge potential.

• (a) Aufladen des Kondensators über eine erste Elektrode des Kondensators während die zweite Elektrode auf einem Entladungspotential liegt;
• (b) Vergleichen des Potentials der ersten Elektrode mit einer Referenzspannung während des Aufladens des Kondensators und Erzeugen eines ersten Steuersignals, sobald die erste Elektrode den Wert der Referenzspannung erreicht;
• (c) Umpolen des Kondensators als Antwort auf das erste Steuersignal;
• (d) Aufladen des Kondensators über die zweite Elektrode des Kondensators;
• (e) Vergleichen des Potentials der zweiten Elektrode mit der Referenzspannung während des Aufladens des Kondensators und Erzeugen eines zweiten Steuersignals, sobald das Potential der zweiten Elektrode den Wert der Referenzspannung erreicht;
• (f) Umpolen des Kondensators als Antwort auf das zweite Steuersignal;
• (g) Wiederholung der Schritte (a) bis (f), wobei die aufeinanderfolgenden Steuersignale die einzelnen Schritte auslösen und das Taktsignal des Multivibrators ergeben.

Furthermore, this object is achieved according to the invention by a method for operating a multivibrator with a capacitor, which contains the following steps:

• (a) charging the capacitor via a first electrode of the capacitor while the second electrode is at a discharge potential;
• (b) comparing the potential of the first electrode with a reference voltage during the charging of the capacitor and generating a first control signal as soon as the first electrode reaches the value of the reference voltage;
• (c) reversing the polarity of the capacitor in response to the first control signal;
• (d) charging the capacitor via the second electrode of the capacitor;
• (e) comparing the potential of the second electrode with the reference voltage during the charging of the capacitor and generating a second control signal as soon as the potential of the second electrode reaches the value of the reference voltage;
• (f) reversing the polarity of the capacitor in response to the second control signal;
• (g) repetition of steps (a) to (f), the successive control signals triggering the individual steps and giving the clock signal of the multivibrator.

Advantageous configurations and Further developments of the invention are characterized in the subclaims.

Other features and advantages of Invention emerge from the following description of preferred embodiments of the invention, which are explained with reference to the drawings. In the drawings demonstrate:

1 a prior art oscillator circuit;

2a and 2 B the oscillator circuit according to the invention in the two different phases of a clock period;

3a a diagram for explaining the course of the voltages on the electrodes of the capacitor used in an oscillator circuit according to the invention during a clock period;

3b that in an oscillator circuit according to the invention during the 3a shown course of the voltages resulting clock signal.

A circuit diagram of an embodiment of an oscillator circuit according to the invention is shown in FIGS 2a and 2 B shown with two different switch positions. The oscillator circuit according to the invention also only requires a capacitor C. This capacitor C is charged alternately from one side and from the other side and the voltage applied to it is compared with a reference voltage. In order to achieve this, some controllable switches S1, ..., S8 are provided which alternately connect the electrodes V1 and V2 of the capacitor C to a current source and ground. In addition, the reference voltage Vref and the electrode of the capacitor connected to the current source are alternately connected to the non-inverting input P and the inverting input N of the comparator K.

In the preferred embodiment of the 2a and 2 B the circuit is designed so that the first electrode V1 of the capacitor C with a first circuit branch 1 is connected and the second electrode V2 of the capacitor C with a second circuit branch z. Both circuit branches 1 and 2 can be connected to a power source via switches S1 and S2 on the one hand and to ground via switches S3 and S4 on the other. The second electrode V2 can be connected via a switch S5 to the non-inverting input P of a comparator K. The first electrode V 1 can be connected to the inverting input N of the comparator K via a switch S6. A reference voltage source Vref can be connected via a switch S7 to the non-inverting input P and via a switch S8 to the inverting input N of the comparator K. The output of the comparator K is connected to the input of a clock-controlled flip-flop 3 connected, which generates the clock signal CLK (= T1) at its one output. The flip-flop output signal T1 is used to control the switches S1, S3, S6 and S7, while the inverted output signal T2 (= T1 ) of the flip-flop is used to control the switches S2, S4, S5 and S8.

2a shows schematically the preferred embodiment of the invention during the first half of a clock period T, in which the switches S1, S3, S6 and S7 are closed and the switches S2, S4, S5 and S8 are open. With these switch positions, the electrode V1 of the capacitor C is charged by the current source Io. The potential arising at the electrode V1 is applied to the inverting input N of the comparator K and compared there with the reference voltage Vref. As soon as the potential of the electrode V1 reaches the value of the reference voltage Vref, the output signal of the comparator K changes and the flip-flop switches, so that the switches S1, S3, S6 and S7 open via the changing output signals T1 and T2 of the flip-flop and the Switches S2, S4, S5 and S8 are closed and the in 2 B shown state results. Now the electrode V 1 is grounded, while the electrode V2 is connected to the power source. As a result, the potential supplied to the non-inverting input P of the comparator K at the beginning of the charging now taking place –Vref, as in the 3a can be seen. During the second half of the cycle time T, the potential of the electrode V2 rises again from -Vref to + Vref.

If the electrode V2 has reached the potential Vref, the output signal of the comparator changes again and the output signals T1 and T2 of the flip-flop are switched over again, which in the 3b can be seen. Now the switches S1, ..., S8 are switched over again and the circuit takes the one in the 2a shown state. The voltage -Vref is now present at the electrode V 1 and a renewed switchover is only achieved when this electrode V 1 has been recharged to + Vref.

In 3a the time course of the charging cycles of the electrodes V 1 and V2 of the capacitor C is shown. By reversing the polarity of the capacitor C twice during a cycle time T and charging the electrodes from -Vref to + Vref during half a cycle time, the available reference voltage is doubled. The cycle time T results from: T = Ctot4Vref / Io, where Ctot is the capacitance of one capacitor, Vref is the reference voltage and Io is the current.

The circuit according to the invention thus saves space by a factor 4 compared to that in 1 circuit shown with the same frequency and the same reference voltage.

Instead of a clock edge controlled Flip flops can be also use another logic circuit that has the same effect achieved.

Claims (5)

Multivibrator with a comparator (K), a capacitor (C), a current source, a reference voltage source and a plurality of switches (S1, ..., S8), characterized in that the switches (S1, ..., S8) so in the Multivibrator lie and can be controlled by the output signal of the comparator (K) that first alternately the reference voltage source with one input (P) of the comparator (K), an electrode (V1) of the capacitor (C) with the current source and the second Input (N) of the comparator (K) and the other electrode (V2) of the capacitor (C) with a discharge potential and then the reference voltage source with the second input (N) of the comparator (K), the other electrode (V2) of the capacitor ( C) with the current source and the first input (P) of the comparator (K) and the first electrode (V1) of the capacitor (C) are connected to the discharge potential. A multivibrator according to claim 1, wherein the discharge potential Mass is. A multivibrator according to claim 1 or 2, further comprising a Contains clock-edge controlled flip-flop, the control input with the output of the comparator (K) is connected and its output signal is the clock signal of the multivibrator. Multivibrator according to one of the preceding claims, the one electrode (V 1) of the capacitor (C) via a first switch (S 1) with the current source, via a second switch (S6) with the second input (N) of the comparator (K) and via one third switch (S4) can be connected to the discharge potential, the other electrode (V2) of the capacitor (C) via a fourth switch (S2) with the power source, over a fifth Switch (S5) with the first input (P) of the comparator (K) and one sixth switch (S3) can be connected to the discharge potential, and the reference voltage source over a seventh switch (S7) with the first input (P) of the comparator (K) and over an eighth switch (S8) with the second input (N) of the comparator (K) is connectable. Method for operating a multivibrator with a capacitor (C) comprising the following steps: (A) Charging the capacitor (C) over a first electrode (V1) of the capacitor (C) while the second electrode (V2) is at a discharge potential; (b) comparing the Potential of the first electrode (V1) with a reference voltage (Vref) during charging the capacitor (C) and generating a first control signal, as soon as the first electrode (V 1) the Wen of the reference voltage (Vref) reached; (c) reversing the polarity of the capacitor (C) in response to the first control signal; (d) charging the capacitor (C) via the second electrode (V2) of the capacitor (C); (e) Compare the potential of the second electrode (V2) with the reference voltage (Vref) during charging the capacitor (C) and generating a second control signal, as soon as the potential of the second electrode (V2) reaches the value of the reference voltage (Vref) reached; (f) reversing the polarity of the capacitor (C) in response to the second control signal; (g) repeating steps (a) through (f), the successive control signals the individual steps trigger and give the clock signal of the multivibrator.