NL8700235A - POWER SOURCE SWITCH. - Google Patents

Description

E 2011-246 Ned hm / hv ^ 4

P&C

PLESSEY OVERSEAS LIMITED

Short designation: Power source switching.

The invention relates to an improvement in current source circuits, in particular type 5 current source circuits comprising one or more drive transistors, for which the base voltage is derived from a reference transistor and a series-connected reference source.

In the design of many integrated circuits, accurate source current is most often an essential requirement, ie it is necessary to generate current which, within a practical tolerance, is constant despite drift or fluctuation in the supply voltage, and effectively independent is of small changes in the transistor parameters.

A current source circuit of the aforementioned type is illustrated in FIG. 1. This circuit thus includes one or more driving transistors T1, .., TN, the base voltage of which is derived from the base of a reference transistor Tg.

This reference transistor T is driven by a current source dS, eg a resistor or a transistor, which is connected in series with the reference transistor T_ between one of the supply voltage rails V_ and the collector of the reference transistor Tg.

The reference transistor T shown has a common connection between its base and its collector. So it functions as a diode. The reference base voltage is derived as a voltage drop across this diode. Provided this reference voltage is kept constant, the current generated by each drive transistor will be proportional to the current from the reference source. In fact, if each drive transistor T ^ to T ^ is matched to the reference transistor T, all drive currents will

O

1 ^ to 1 ^ ideally equal to the source current. However, if the reference transistor Tg and drive transistors T ^ to T ^ are of different geometry by design, the currents 1 ^ to 1 ^ will be scaled to the reference current I by a geometric factor.

In practical source circuits, however, a finite base current is drawn through each drive transistor T ^ to T ^. As a result, an error is introduced into the reference voltage. This error will increase proportionally to the number N of the driving transistors. In particular, it is noted that this error is most pronounced where the drive transistors T ^ to T ^ are of PNP construction. PNP transistors show a low current gain and thus draw an important base-40 current.

8700235 J »-2-

The aforementioned problem is usually overcome by means of a complex mirror, an example of which is shown in Fig. 2. In this modification, the short circuit of the transistor ("short") 5 is replaced by a second reference transistor T '. The emitter and base of

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the latter transistor Tg 'are connected across the base and collector of the first reference transistor T as shown. However, it is a drawback of this solution that a supply voltage of at least twice the voltage drop between base and emitter of the transistors, ie a supply voltage of at least 2V ^ e (usually 1.4Vj) is required. 1.5V batteries are commonly used to power such circuitry Typically, these batteries will deliver a power which drops to a voltage at the end of their life of about 0.9V. However, in the circuit described in Figure 2, once the battery voltage drops below 1.4V or the like, it must be replaced, ie it must be replaced, while power is still available, even at a lower voltage.

Another problem that can arise is that of Early voltage effects. As the emitter-collector voltage increases, the collector-20 current from the drive transistors may rise to levels higher than the reference value.

The present invention is intended to provide a remedy. It provides a circuit that will operate even at increasingly lower supply voltages, ie voltages typically below 1.4V and below, say, 0.9V and even lower, while remaining able to provide a constant current despite variations in the supply voltage and transistor parameters.

Accordingly, the invention provides a power source circuit of the type comprising one or more driving transistors, the base voltage of which is derived from a first reference transistor and series-connected reference source, characterized by a feedback control sub-circuit comprising: - a power supply transistor, of which the collector is connected to the base of the reference transistor; 35 - a diode connected to the base of the power supply transistor; and - a second reference transistor connected in series with the diode, the base of the second reference transistor connected to a node between the first reference transistor and the reference source.

The diode can be most conveniently provided by 40 a transistor, the base and collector of which are connected together.

8700235 * *.

-3-

Ideally, this transistor can be matched in properties to the aforementioned power supply transistor.

Said circuit may be supplemented with a bias voltage diode and an additional bias current source, which are connected in series between power rails, their node being connected to the base of each driving transistor. In this case, the bias current is corrected by current in the feedback sub-circuit. The latter diode can be omitted. The bias source can only be used to provide current start-up and / after equilibrium conditions are obtained, removed from the circuit, a switch being incorporated between the bias source and the common base connections of the reference transistor and each drive transistor . Other means of providing a power start-up are not excluded.

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

FIGURES 1 and 2 show circuit diagrams of two known current source circuits; and FIGURES 3-5 show circuit diagrams of three different source circuits, each constructed in accordance with the invention.

The current source circuit shown in FIG. 3 includes a plurality of driving transistors whose bases are jointly connected to the base of a reference transistor T, which in turn is driven by a reference current source S. The base of the latter transistor T is connected to the collector output of a power supply transistor b

tor T. The base of this power supply transistor T is in turn connected F F

with a diode and transistor circuit, comprising a transistor TQ (diode), the base and collector of which are shorted together and matched, and a second reference transistor T ', which are connected in series between the supply rails V and V. The basic voltage for / driving the second

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reference transistor T1 is taken from the collector output of the first b reference transistor T, ie from a node between this last transistor T1 and the reference source S. As shown in FIG. 3, this circuit also includes a bias diode T, e.g. a shorted transistor, and a bias current source B. The latter are connected in series between the power rails, and their node is connected in common with the bases of the driving transistors to and the first reference transistor Tg.

40 In this figure work up to as described previously, but under 8700235:? * -4- using the bias current source B. The current Ig will flow from T tot into the reference current source S. The control loop T, T, T will supply current S Γ X b to current source B to keep the coCector current of T b

5 to the reference current source S. This fixes the collector currents of T, T

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and any other transistor T ^ connected to be the same as the reference S. Current source B is non-critical. It is only required that

its current I must be greater than the reference current I of the re-BS

source of frequency S, plus the maximum expected base currents, for the circuit 10 to function. Since the base currents are supplied by the bias current source B, the output current is independent of the transistor gain factor.

This current will also take into account the Early effect on the drive transistors. The collector of will often be used to power the diode of another current mirror. This causes the collector current to rise, due to Early effect, when the supply voltage increases; ignoring the effect of the current mirror control circuit. In this design, T 'functions in the same manner as T. and

b X

therefore sees the same Early effect. As the supply voltage increases, the current in T will tend to increase, but the feedback b loop will reduce the base drive to sufficient to keep the current in Tg equal to Ig. follows Tg and is thus compensated for its Early effect. The reference source S is protected from Early effect problems because Tg 'keeps its output at a constant voltage.

The circuit described will operate with a supply voltage of only 0.7V.

In Fig. 4, Τβ has been removed. The bias current source B only has to provide the expected maximum base current. This arrangement can reduce the total supply current if required for low current operation. In Fig. 5, the power source B itself has been removed. The circuit will now not start to operate when turned on, since it is in a stable state with all currents at zero. A start-up circuit is necessary to start the operation of the circuit. A short connection to the power source B (via a switch S) will suffice for this, but many other devices are possible.

Immediate application in integrated circuits is intended for "radio paging". The circuit design for "pagers" is not without complications due to the low battery-40 voltage, end of life at 0.9V, and low power consumption. The need

87 0 023 S

RESUME

-5- for battery economy will also involve extensive use of power mirrors in the circuit design.

The circuits just described, although designed for "pagers1", could be used advantageously on any low power and low current circuit.

10 15 20 25 30 35 40 8 700 235

Claims (5)

1. Power source circuit (Fig. 3-5) of the type comprising one or 5 more driving transistors (T ^, .. T ^), for which the base voltage is derived from a first reference transistor (T) and series-connected reactors. b source of frequency (S), characterized by a feedback-control sub-chain consisting of: - a power supply transistor (T), the collector of which is connected to the base of the reference transistor (T); w - a diode (T) connected to the base of the power supply transistor (T); and DF - a second reference transistor (T '), connected in series with the diode O' (T), the base of the second reference transistor (T ') connected O o to a node between the first reference transistor (T) and the reference 15 source of information (S). Circuit according to claim 1, characterized in that said diode (Tp) comprises a transistor, the base and collector of which are connected to each other. Circuit (Fig. 3) according to claim 1 or 2, characterized by a further bias diode (T) and additional bias source (B), wherein O at the junction between these two circuit components is connected to the base of the first reference transistor ( T). O Circuit (Fig. 4) according to claim 1 or 2, characterized in that the additional bias voltage source (B) is further connected to the base 25 of the first reference transistor (T). O Circuit (Fig. 5) according to claim 4, characterized by a switch (S) between the additional bias source (B) and the base of the first reference transistor (T). O 30 35 40 1700 235 '