NL8702011A - Supply stabiliser for electronic circuits - has transistor between collectors of current mirror transistors - Google Patents

Abstract

The stabiliser consists of a current mirror amplifier (T21, T22), a servo transistor (T24) connected to the commoned bases of the amplifier and a regeneration circuit (T23, T25, R21). The usual resistor and diode arrangement is replaced by a sixth transistor (T27) connected between the collectors of the current mirror transistors (T21, T22). The base and collector of the sixth transistor are connected to form a diode. Other versions have different types of stabiliser with similar start-up circuits.

Description

* PHN 12,240 1 N.V. Philips' Incandescent light factories in Eindhoven.

Start circuit for a stabilization circuit.

The invention relates to a stabilization circuit comprising - a current mirror amplifier, at least provided with a first and a second transistor, the emitter-collector paths of which are connected between a first supply voltage connection and a first and a second current output, respectively, and the bases of which are connected to each other if connected to the second current output; a third transistor whose emitter-collector path is connected between the second current output and the second supply voltage terminal; a reference circuit, included between the first current output and the second supply voltage connection, which reference circuit supplies control signals to the base of the third transistor.

Such a stabilization circuit is already known in a number of variants. Examples are described in US-A-4,051,392, US-A-4,083,359 and the book "Analysis and design of analogue integrated circuits" by P.R. Gray and R.G. Meyer, 1984 edition.

As is known, such stabilization circuits generally have two stable states, namely a first state in which no current flows at all through the various transistors and a second state in which the current outputs supply the desired currents. In order to avoid that the circuit remains in the first stable state after the supply voltage has been switched on, in which no current is supplied and the circuit therefore does not fulfill the desired function, so-called starting circuits are used, which stabilize the circuit after the supply voltage has been switched on. bring certainty to the second stable state in which the circuit fulfills its desired function.

When the circuit has reached the second stable state, the starting circuit is no longer necessary. It must now be ensured that the presence of the starting circuit does not affect the normal operation of the stabilizing circuit. In general, therefore, 8702011 * * PHN 12.240 2, starting circuits are designed so that automatic decoupling takes place between the starting circuit and the stabilizing circuit as soon as the latter has reached its desired operating point.

A drawback of the known starting circuits is that these circuits continue to consume power even after the stabilizing circuit has reached its operating point, which is experienced as a major drawback, particularly in integrated circuits, which strive for the lowest possible power consumption. In many known starting circuits, moreover, relatively large resistors are required, which require a lot of space in integrated form.

The invention now has for its object to provide a starting circuit for a stabilizing circuit, which no longer absorbs power after the stabilizing circuit has been brought into its operating point and which further consists of only a very small number of components which are simply integrated together with components of the stabilizing circuit can be realized.

This invention is fulfilled in a stabilizing circuit of the type mentioned in the preamble, in that the stabilizing circuit is provided with a starting circuit consisting of a diode which is switched in the forward direction between the first and second current output.

The invention will be explained in more detail below with reference to the accompanying figures.

Figures 1A, B, C show a number of stabilization circuits known from the prior art, each with an associated starting circuit.

In Figs. 2A, B, C the stabilization circuits from the corresponding Figs. 1a, 1b, 1c are again shown, now provided with a starting circuit according to the invention.

First of all, a number of known stabilization circuits, each comprising a starting circuit, will be briefly discussed with reference to Figures 1a, 1b, 1c. For detailed details, reference is made to the 35 references listed below.

Figure 1A shows a stabilization circuit of a type as described, for example, in US-A-4,051,392. This known circuit 8702011

V

PHN 12.240 3 includes a current mirror amplifier formed by the first and second transistors and T2. The emitters of and T2 are connected to the supply voltage rail V +, the bases of the two transistors are mutually connected and the collector of T2 is also coupled to these mutually connected bases. In this configuration, transistors T1 and T2 supply mutually equal collector currents to the underlying regenerative circuit consisting of the third transistor T3, the fourth transistor T4 and the resistor R1. When both transistor T3 and transistor 10 are conductive during operation, a voltage drop across the resistor is created which must be equal to the base-emitter voltage of T1. Should the current through T3 decrease, resulting in a drop in the voltage drop across R1, T4 tends to be pinched so that its collector voltage rises further opening T3 and counteracting the current drop through T3. The feedback configuration of T3 and T4 therefore tends to adjust to currents through both transistors having a predetermined mutual relationship. In this circuit, therefore, a reference circuit supplies current to the base of the third transistor T3.

As is known, such a circuit has two stable operating points in which both the current conditions of the current mirror amplifier and those of the regenerative circuit T3 / T4 are met. In the first stable operating point, no current flows at all through the circuit and in the second stable operating point, predetermined currents flow, the values of which depend, inter alia, on the value of the resistor R |.

Due to the stable operating point in the zero current situation, it is necessary to use a starting circuit which avoids the stabilization circuit remaining in the zero current situation after the supply voltage is switched on. In figure 1a this starting circuit is provided with the transistors T5 and Tg and the resistor R2.

If no current flows through T2 after switching on the supply voltage, the base voltage of Tg will be too low to conduct this transistor. The collector of Tg and thus the base of Tg therefore carries a high potential so that 8702011 PHN 12.240 4

Tg will conduct, opening a flow path through T2 and Tg. As current flows through T2, current will also flow through T ^, the circuit around T3 and T4 will also come into operation and the circuit will adjust to the other desired operating point. Once this operating point has been reached, the basic voltage of Tg will now be sufficient to initiate Tg and thereby block Tg. Therefore, apart from the base current of Tg, the starting circuit is decoupled from the stabilizing circuit. However, the starting circuit continues to draw power from the supply voltage source V via R2 and Tg.

Figure 2A shows in principle the same stabilization circuit as in figure 1A, but now provided with a starting circuit according to the invention. The components of the actual stabilization circuit are identified by the same reference characters: 15 T ^, T2, T3, T ^ and. As can be seen from Figure 2A, the starting circuit in fact only consists of the transistor T7, which, connected as a diode, is arranged between the collectors of T1 and T2. If after switching on the supply voltage the circuit enters the zero current situation, due to the presence of 20 Ίη, a current path can still be opened going through T2, T? and T4 between the supply voltage terminals V + and V-. As soon as current flows through this path, the circuit as a whole, in the manner already discussed, will be drawn to its active operating point. Once this desired operating point has been reached, the voltages on the 25 collectors of T ^ and T2 will be equal or almost equal to each other, so that the collector-emitter voltage of Ίη is equal to zero or to a very small value that is in any case insufficient is to pass some current through this transistor. Therefore, as soon as the stabilizing circuit has set itself in its active operating point, the starting circuit, formed by T7, is automatically switched off.

A second known stabilization circuit is shown in Figure 1B. Such a circuit has already been described in US-A-4,085,359. The current mirror amplifier in this circuit is formed by T ^ and T ^ · The regenerative circuit is formed by T13, T. | 4 and the resistor R ^. In this circuit, the transistors T13 and T14 operate at different current densities such that the base-emitter voltage of transistor T ^ 3 is less than that of 870 201 1 PHN 12.240 5 of T ^. The voltage across the resistor at a given collector current of is therefore equal to the difference between the base emitter voltages of the transistors and T ^. This stabilizing circuit also has two stable states, a first state in which no current flows through the circuit and a second state in which currents flow, the magnitude of which can be varied, among other things, by setting R 1.

The starting circuit described in US-A-4,085,359 is formed by T15 'the resistors and R ^ and the diodes D ^ and 10 D2 · After the supply voltage is switched on, a current will flow through R-j2, D.jf D2 so that a base voltage is applied to the transistor T15 sufficient to conduct it. As a result, a current will flow from the positive supply voltage terminal v + through TT-j5 and R ^ to the negative supply voltage terminal V-. Since T ^ comes into conduction, conduction will now also be controlled, in other words current will flow in both branches of the current mirror amplifier, also in both branches of the regenerative circuit and soon the entire stabilization circuit will adjust to the desired operating point.

When the desired operating point is reached, the voltage drop across D1 and D2 is no longer sufficient to keep transistor T-jg conducting in view of the voltage drop across Rj. This transistor T-jg is therefore turned off, so that, apart from a leakage current through Rj, the connection between the starting circuit and the stabilizing circuit is in fact broken. However, the starting circuit itself continues to draw power through R.j2, D. | and D2 from the supply voltage source, which is considered undesirable.

Figure 2B shows the use of a starter circuit according to the invention in a stabilization circuit of the type shown in Figure 1B. In Fig. 2B, the components of the actual stabilization circuit are again indicated with the same reference numerals as in Fig. 1B. The operation of the starting circuit, in this case formed by transistor T1, is in fact identical to the operation as described in figure 2A and therefore needs no further explanation.

Figure 2c shows the use of the stabilization circuit according to the invention in a stabilization circuit of the type shown in Figure 1c. Here too, correct reference indications have been used for the actual 8702011 # PHN 12.240 6 stabilization circuit.

Figure 1C shows another known stabilization circuit of a type described in various variants in DE-A-34.47.002, among others. In this circuit, the current mirror amplifier 5 is formed by Τ2Ί and Τ22ι with T24 added as a slave of T22 to this configuration. Only the collector of T22 is fed back to the common terminal of the base of said three transistors. The regenerative circuit is formed by the transistors T23 and T25 and the resistor R21-10. This circuit also has a first stable operating point in the zero current state and a second stable operating point at which the currents supplied by the current mirror amplifier will be just so great that the voltage drop across R21 is equal to the base-emitter voltage across T25 and the collector-emitter voltage across T25 is just large enough to drive T23 open with the same current through both T23 and T25. Due to the two possible stable operating points, this circuit also requires a starting circuit to get to the correct operating point after the supply voltage has been switched on.

In this circuit, a starting circuit of the type described in Figures 1A and 1B can be used. An example thereof, comprising the resistor R22 of the diodes D3 and is illustrated in Figure 1C. However, this configuration also has the drawback that after reaching the desired operating point, current continues to flow through R22 and D4.

Figure 2C shows the use of a starting circuit according to the invention in this known stabilization circuit. The transistor T2 ^ is again connected between the collectors of the two transistors from the current mirror amplifier, namely T2i and T22 ·

Should the circuit end up in the zero current situation after the supply voltage is switched on, a current path will still be formed directly via T22, T27 and R21, whereby the circuit is withdrawn from the zero current situation and eventually returns to the desired second stable operating point.

Figure 3 shows a further development of the circuit 35 of Figure 2A. For the sake of clarity, the same reference characters have been used for corresponding components. The only difference between Figure 3 and Figure 2A is the addition of the resistors R. ^ 870201 1 PHN 12.240 7 and R32, respectively, between the second current output of the current mirror amplifier and the cathode of the diode-connected transistor Tη, respectively, between the anode of the diode-switched transistor Ύη and the reference source from the regenerative circuit Tj / T ^ / Rj. With the help of resistors R ^ and R32, the limits at which the starting circuit operates can be varied as desired. Adding the resistor R ^ leads to a decrease in the base voltage of Ύη while adding R ^ increases the collector voltage of this transistor. Assuming that at a base-emitter voltage less than zero, no current flows through transistor Ύη, the following relationship applies to the circuits shown in Figures 2A and 3: vsmax- <3% + I (% + * 32> where V.

= maximum supply voltage 15 Vg £ = base emitter voltage of Ύη I = current supplied by the current mirror amplifier.

It will be appreciated that also in the configurations of Figures 2B and 2C, the resistors R1 and R32 (or only one of the two resistors) may be added as desired to properly set the operating path depending on the remaining circuit requirements. of the starting circuit. For the figures 2B and 2C the following relationship then applies: V5W2VBE + I <r31 «32> in which VSfflax = maximum supply voltage 25 VBE = base emitter voltage of T17 and T27 I = current supplied by the current mirror amplifier.

8702011

Claims (4)

Stabilizing circuit comprising - a current mirror amplifier, at least provided with a first and a second transistor, the emitter-collector paths of which are connected between a first supply voltage connection and a first and a second current output, respectively, and whose bases both with each other and with the second current output are connected; a third transistor, the emitter-collector path of which is connected between the second current output and the second supply voltage connection; 10. a reference circuit included between the first current output and the second supply voltage terminal, which reference circuit supplies control signals to the base of the third transistor, characterized in that the stabilization circuit comprises a starting circuit consisting of a diode which is connected in the forward direction between the 15 second and first current output. Stabilizing circuit according to claim 1, characterized in that a resistor element is included between the emitter-collector path of the second transistor and the second current output. Stabilizing circuit according to claim 1, characterized in that a resistance element is included between the first current output and the reference circuit. Stabilizing circuit according to claim 1, characterized in that a resistor element is included between the emitter-collector path of the second transistor and the second current output and a further resistor element is included between the first current output and the reference circuit. 8702011