Regulated voltage generator for integrated circuit

Abstract

A regulated voltage generator provides different regulated voltages to an integrated circuit. The regulated voltage generator includes a bandgap reference circuit and at least one gain stage connected to an output thereof. The output voltage of the bandgap reference circuit varies as a function of temperature to compensate for variations in the gain stage made up of first and second transistors. A regulated voltage output by the regulated voltage generator is independent of temperature and of the supply voltage. The value of the regulated voltage is adjusted via a load resistor and via the first and second transistors along with an output transistor of the bandgap reference circuit.

Description

FIELD OF THE INVENTION

The present invention relates to integrated circuits, and more particularly, to voltage generators which provide different reference voltages required for supplying integrated circuits.

BACKGROUND OF THE INVENTION

External power supplies for integrated circuits now vary between three volts and ten volts, whereas the voltages required by the internal power supplies for the electrical circuits within the integrated circuits are, depending on the application, 2.5 volts, 3 volts, 5 volts and 7 volts. These voltages are within ±10%. It is therefore imperative that an integrated circuit itself generate these different voltages in order that they be independent of the power supply voltage and of temperature. For instance, the temperature may vary between −40° C. and 125° C.

To this end, there has been proposed a regulated voltage generator which exploits the properties of a reference voltage given by a circuit described in an article by E. Vittoz and J. Fellrath, entitled “CMOS Analog Integrated Circuits Based on Weak Inversion Operation”, published in IEEE Journal of Solid State Circuits, Vol. SC-12, no. 3, 1997, pages 224-231. This voltage reference circuit is generally known as a bandgap voltage reference circuit.

This prior art circuit supplies a reference voltage of 1.28 volts, known as the bandgap voltage, which is constant over a wide range of supply voltages and temperatures. To obtain the different required voltages, the circuit's output voltage is applied to gain stages, with each gain stage producing one of the required voltages.

However, these gain stages are sensitive to the supply voltage and to temperature, and the same holds for the power stage that follows them for supplying the required power. As a result, the voltages supplied vary significantly as a function of power supply voltage and of the temperature.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a generator for at least one regulated voltage that is not very sensitive to variations over a wide range of power supply voltages and temperatures.

This object is achieved by using a potential barrier reference voltage circuit, known as a bandgap type of circuit, and at least one gain stage. To provide a regulated voltage generator that is not sensitive to variations in the power supply voltage and temperature, the characteristics of the reference voltage are degraded to compensate for the variations due to the gain stage. The reference voltage then delivers a voltage which is a function of temperature variations opposite to that of the gain stage.

Another object of the present invention is to provide a generator producing a plurality of regulated voltages by implementing several gain stages.

The invention thus relates to a regulated voltage generator for supplying at least one regulated voltage to an integrated circuit comprising a bandgap type of reference voltage circuit and at least one gain stage. The bandgap type of reference voltage circuit comprises a current generator which supplies a bipolar transistor configured as a diode via a load resistor connected to the emitter of the bipolar transistor.

The gain stage comprises two MOS transistors in series between the supply voltage and a ground potential. The gate of a first transistor is connected to the gate of the output transistor of the current generator, and the gate of the second transistor is connected to the output of the bandgap type reference voltage circuit.

The characteristics of the first and second transistors are chosen to obtain the regulated voltage. The value of the load resistor is chosen such that the emitter-base voltage of the bipolar transistor varies with temperature in a manner to compensate for the variation of the gate-source voltage of the second transistor as a function of temperature.

BRIEF DESCRIPTION OF THE DRAWINGS

Other characteristics and advantages of the present invention shall become more apparent from reading the following description of the preferred embodiments, given with reference to the appended drawings in which:

FIG. 1 is a schematic circuit diagram of a regulated voltage generator in accordance with the present invention; and

FIG. 2 is a block diagram of a device which delivers a regulated voltage among several available voltages in accordance with the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The regulated voltage generator 10 in accordance with the invention comprises ( FIG. 1 ) a bandgap (potential barrier) reference voltage circuit 12 and at least one gain stage 14 . The circuit 12 comprises four transistors M 1 , M 2 , M 3 and M 4 which are connected in a closed loop.

Transistors M 1 and M 2 are N-type MOS transistors whose sources are connected to a terminal at ground potential GND, either directly for transistor M 2 , or via a resistor R for transistor M 1 . The gates of transistors M 1 and M 2 are connected to one another and to the drain of transistor M 2 , which is connected to the drain of MOS transistor M 4 . Transistor M 4 is a P-type transistor, and its source is connected to the supply voltage V PS . The gate of transistor M 4 is connected to the gate and to the drain of MOS transistor M 3 , which is a P-type transistor, and is connected to the drain of transistor M 1 . The source of transistor M 3 is connected to the supply voltage V PS .

The gates of transistors M 3 and M 4 are connected to the gate of a P-type MOS transistor M 5 whose source is connected to the supply voltage V PS . The drain of transistor M5 is connected to the ground potential GND via a resistor R 2 , and a PNP type bipolar transistor Q 1 is connected as a diode. Bipolar transistor Q 1 has its emitter connected to a terminal of resistor R 2 while its other two electrodes are connected to the ground potential GND so that it functions as a diode.

The bandgap type reference voltage circuit 12 has two output terminals 16 and 18 . One output terminal 16 corresponds to the common node of the gates of transistors M 3 , M 4 and M 5 , and the other output terminal 18 corresponds to the drain of transistor M 5 .

The gain stage 14 comprises two P-type MOS transistors M 6 and M 7 . The gate of transistor M 6 is connected to output terminal 16 , while the gate of transistor M 7 is connected to output terminal 18 . The source of transistor M 6 is connected to the supply voltage V PS , while its drain is connected to the source of transistor M 7 . The drain of transistor M 7 is connected to the ground potential GND. The regulated output voltage VG 2 is taken from the terminals of transistor M 7 , i.e., between the ground potential GND and the source of transistor M 7 .

Transistors M 1 to M 5 and resistor R form a current source producing a current I GT . This current is supplied by transistor M 5 , and flows through resistor R 2 and bipolar transistor Q 1 . Transistor Q 1 is connected as a PN diode, and the current IGT varies proportionally with temperature.

In a prior art bandgap type of reference voltage circuit, the value of R 2 is chosen to produce a voltage V GAP ≈1.28 volts at the terminals of Q 1 and R 2 , which is not sensitive to temperature. This voltage V GAP is used in the gain stage 14 to obtain the required voltage VG G2 , which is greater than V GAP .

In this gain stage, since the output voltage VG G2 is the sum of V GAP and the voltage V SG7 between the gate and the source of transistor M 7 , with V SG7 varying with temperature, V G2 also varies with temperature.

The invention includes making V GAP vary, so that it becomes V* GAP , as a function of temperature in order to compensate for the variation of V SG7 as a function of temperature. This is obtained by adjusting the value of resistor R 2 and the sizes of transistors M 5 , M 6 and M 7 .

To this end, a first equation defines the current I GT :

I GT ( T )≈ I GT ( T 0 )×( T/T 0 )  (1)

with the temperature T being expressed as an absolute value, and the temperature To being the reference temperature of 27° C.

A second equation defines the output voltage V G2 such that:

V G2 =V * GAP +V SG7 ≈V EB +R 2 I GT +V T7 η 2 I GT   (2)

where

V EB is the emitter-base voltage of transistor Q 1 ,

η 2 is a term which depends on the W/L coefficients of transistors M 5 , M 6 and M 7 ,

V T7 is an intrinsic characteristic voltage of transistor M 7 , referred to as the threshold voltage, and

V* GAP is the variable voltage which depends on the temperature at the terminals of resistor R 2 and of bipolar transistor Q 1 . This is the output voltage of the bandgap reference voltage stage.

A third equation defines the variation of 72 2 as a function of temperature:

η 2 ( T )≈η 2 ( T 0 )( T 0 /T ) m   (3)

with m being in the region of two.

These three equations (1), (2) and (3) make it possible to determine the values of η 2 and R 2 by the following formulas:

η 2 ≈0.4[( V G2 −V EB +V V7 )− T 0 (δ V EB /δT )]/[ I GT ( T 0 )]  (4a)

R 2 =0.2[3( V G2 −V EB +V T7 )+2 T 0 ( δV EB /δT ) ]/[I GT ( T 0 )]  (4b)

with δV EB /δT being in the region of 1.8 mV/°C.

These two formulas lead to values of R 2 =550 kΩ and η 2 =493 to obtain a value V G2 =2.94 volts, which varies by 300 μV/° C., that is 49.5 mV in the temperature range of −40° C. to +125° C. for V PS =10 volts.

The voltage V* GAP can be used to obtain other voltages V G1 and V G3 by applying that voltage to two gain stages 14 ′ and 14 ″ in which the transistors M′ 6 , M′ 7 and M″ 6 , M″ 7 are determined by the coefficients η 1 and η 3 calculated using formula (4a). Calculated values of η 2 =493 for V G1 =2.46 volts and η 3 =635 for VG G3 =3.43 volts are provided, for example.

However, these voltages V G1 and V G3 are sensitive to temperature variations, on the order of a millivolt per degree Celsius. To obtain a voltage V G1 or V G3 that would not be sensitive to temperature, it would be necessary to modify R 2 according to formula (4b) to obtain R 1 , for the case of voltage V G1, and R 3 for the case of voltage VG 3 .

Moreover, coefficient η 2 not only determines the characteristics of transistors M 6 and M 7 , but also transistor of M 5 according to the formula: $$ η 2 = [ W6 · L5 / W5 · L6 ] 1 / 2 [ μ ⁢   ⁢ 7 · Cox ⁡ ( W7 / L7 ) ] 1 / 2

where:

W and L are respectively the width W and the length L of the drain-source channel of transistors M 5 (W 5 and L 5 ), M 6 (W 6 , L 6 ) and M 7 (W 7 , L 7 ), μ 7 is the mobility of transistor M 7 , and Cox is the oxide capacitance.

FIG. 2 is a functional block diagram of a device which supplies one of the three voltages V G1 , V G2 or V G3 on demand. This device comprises the bandgap type reference voltage circuit 12 of the diagram in FIG. 1 , and supplies on output terminal 18 the voltage V* GAP as well as the voltage V GT of transistor M 5 on output terminal 16 . Output terminals 16 and 18 are connected to the input terminals of the gain stages 14 ′, 14 and 14 ″, which respectively supply the voltages V G1 , V G2 and V G3 .

Only the voltage V G2 which corresponds to the value R 2 calculated from formula (4b) is in fact regulated, and hence substantially independent of temperature variations. The output terminals of gain stages 14 ′, 14 and 14 ″ are each connected to one of three input terminals 22 , 24 , 26 of a multiplexing circuit 30 which produces the connection between one of the three input terminals 22 , 24 , 26 and its output terminal 28 . Selection of the connection is obtained by a control circuit 32 using appropriate signals.

The output terminal 28 of the multiplexing circuit 30 is connected to the input terminal of a power amplifier 34 , whose output terminal 36 is connected to an electronic circuit to be supplied, such as a microprocessor 38 , for example.

Claims

1. A regulated voltage generator for supplying at least one regulated voltage to an integrated circuit, the regulated voltage generator comprising:a bandgap reference voltage circuit comprising a load resistor, a bipolar transistor configured as a diode and including an emitter connected to said load resistor, and a current generator comprising an output transistor for supplying a current to said bipolar transistor via said load resistor; and at least one gain stage connected to an output of said bandgap reference voltage circuit for supplying the at least one regulated voltage, said at least one gain stage comprising a first MOS transistor including a gate connected to a gate of said output transistor, and a second MOS transistor connected in series to said first MOS transistor between a supply voltage and a voltage reference, said second MOS transistor including a gate connected to the output of said bandgap reference voltage circuit, characteristics of said first and second transistors determining the at least one regulated voltage, said load resistor having a value so that an emitter-base voltage of said bipolar transistor varies with temperature to compensate for a variation of a gate-source voltage of said second transistor as a function of temperature.

2. A regulated voltage generator according to claim 1, wherein the characteristics (η2) of said first and second MOS transistors are defined by the formula: η2≈0.4[(VG2−VEB+VT7)−T0(δVEB/δT)]/[IGT(T0)]in which:VG2 is a value of the at least one regulated voltage to be obtained, VEB is the emitter-base voltage of said bipolar transistor, VT7 is a threshold voltage of said second MOS transistor M7, T0 is a reference temperature, IGT is a current supplied by said current generator, and δVEB/δT is a variation of the emitter-base voltage VEB as a function of temperature T.

3. A regulated voltage generator according to claim 2, wherein the value of said load resistor (R2) is defined by the formula:R2=0.2[3(VG2−VEB+VT7)+2T0(δVEB/δT)]/[IGT(T0)].

4. A regulated voltage generator according to claim 1, wherein said at least one gain stage comprises a plurality of gain stages, with each gain stage providing a respective regulated voltage, the regulated voltage generator further comprising:a multiplexing circuit connected to said plurality of gain stages for receiving the plurality of regulated voltages; and a control circuit connected to said multiplexing circuit for selecting one of the plurality of regulated voltages for output.

5. A regulated voltage generator according to claim 4, further comprising a power amplifier connected to an output of said multiplexing circuit for amplifying the regulated voltage selected by said control circuit.

6. A voltage generator for supplying at least one regulated voltage and comprising:a bandgap reference voltage circuit comprising a load resistor, a load transistor connected to said load resistor, and a current generator comprising an output transistor for supplying a current to said load transistor via said load resistor; and at least one gain stage connected to an output of said bandgap reference voltage circuit for supplying the at least one regulated voltage, said at least one gain stage comprising a first transistor including a control terminal connected to a control terminal of said output transistor, and a second transistor connected in series to said first transistor between a supply voltage and a voltage reference, said second transistor including a control terminal connected to the output of said bandgap reference voltage circuit, said load resistor having a value so that a conducting terminal/control terminal voltage of said load transistor varies with temperature to compensate for a variation of a control terminal/conducting terminal voltage of said second transistor as a function of temperature.

7. A regulated voltage generator according to claim 6, wherein said load transistor comprises a bipolar transistor including a base, an emitter and a collector, with the collector and base being connected together so that said load transistor is configured as a diode, and with the emitter being connected to said load resistor.

8. A regulated voltage generator according to claim 7, wherein the conducting terminal/control terminal voltage of said load transistor comprises an emitter-base voltage thereof.

9. A regulated voltage generator according to claim 6, wherein said first and second transistors each comprises a MOS transistor.

10. A regulated voltage generator according to claim 9, wherein said second MOS transistor includes a gate and a source, and wherein the control terminal/conducting terminal voltage of said second MOS transistor comprises a gate-source voltage thereof.

11. A regulated voltage generator according to claim 6, wherein the characteristics (η2) of said first and second transistors are defined by the formula:η2≈0.4[(VG2−VEB+VT7)−T0(δVEB/δT)]/[IGT(T0)]in which:VG2 is a value of the at least one regulated voltage to be obtained, VEB is the conducting terminal/control terminal voltage of said load transistor, VT7 is a threshold voltage of said second transistor M7, T0 is a reference temperature, IGT is a current supplied by said current generator, and δVEB/δT is a variation of the conducting terminal/control terminal voltage of said load transistor voltage VEB as a function of temperature T.

12. A regulated voltage generator according to claim 6, wherein the value of said load resistor (R2) is defined by the formula:R2=0.2[3(VG2−VEB+VT7)+2T0(δVEB/δT)]/[IGT(T0)].

13. A regulated voltage generator according to claim 6, wherein said at least one gain stage comprises a plurality of gain stages, with each gain stage providing a respective regulated voltage, the regulated voltage generator further comprising:a multiplexing circuit connected to said plurality of gain stages for receiving the plurality of regulated voltages; and a control circuit connected to said multiplexing circuit for selecting one of the plurality of regulated voltages for output.

14. A regulated voltage generator according to claim 13, further comprising a power amplifier connected to an output of said multiplexing circuit for amplifying the regulated voltage selected by said control circuit.

15. An electronic circuit for supplying a plurality of regulated voltages and comprising:a bandgap reference voltage circuit comprising a load resistor, a load transistor connected to said load resistor, and a current generator comprising an output transistor for supplying a current to said load transistor via said load resistor; and a plurality of gain stages connected to an output of said bandgap reference voltage circuit for providing the plurality of regulated voltages, each gain stage comprising a first transistor including a control terminal connected to a control terminal of said output transistor, and a second transistor connected in series to said first transistor between a supply voltage and a voltage reference, said second transistor including a control terminal connected to an output of said bandgap reference voltage circuit, said load resistor having a value so that a conducting terminal/control terminal voltage of said load transistor varies with temperature to compensate for a variation of a control terminal/conducting terminal voltage of said second transistor as a function of temperature; a multiplexing circuit connected to said plurality of gain stages for receiving the plurality of regulated voltages; and a control circuit connected to said multiplexing circuit for selecting one of the plurality of regulated voltages for output.

16. An electronic circuit according to claim 15, wherein said load transistor comprises a bipolar transistor including a base, an emitter and a collector, with the collector and base being connected together so that the load transistor is configured as a diode, and with the emitter being connected to said load resistor.

17. An electronic circuit according to claim 16, wherein the conducting terminal/control terminal voltage of said load transistor comprises an emitter-base voltage thereof.

18. An electronic circuit according to claim 15, wherein said first and second transistors each comprises a MOS transistor.

19. An electronic circuit according to claim 18, wherein said second MOS transistor includes a gate and a source, and wherein the control terminal/conducting terminal voltage of said second MOS transistor comprises a gate-source voltage thereof.

20. An electronic circuit according to claim 15, wherein the characteristics (η2) of said first and second transistors are defined by the formula:η2≈0.4[(VG2−VEB+VT7)−T0(δVEB/δT)]/[IGT(T0)]in which:VG2 is a value of the at least one regulated voltage to be obtained, VEB is the conducting terminal/control terminal voltage of said load transistor, VT7 is a threshold voltage of said second transistor M7, T0 is a reference temperature, IGT is a current supplied by said current generator, and δVEB/δT is a variation of the conducting terminal/control terminal voltage of said load transistor voltage VEB as a function of temperature T.

21. An electronic circuit according to claim 15, wherein the value of said load resistor (R2) is defined by the formula:R2=0.2 [3(VG2−VEB+VT7)+2T0(δVEB/δT)]/[IGT(T0)].

22. A method for making a voltage generator for supplying at least one regulated voltage, the method comprising:providing a bandgap reference voltage circuit comprising a load resistor, a load transistor connected to the load resistor, and a current generator comprising an output transistor for supplying a current to the load transistor via the load resistor; providing at least one gain stage comprising a first transistor including a control terminal connected to a control terminal of the output transistor, and a second transistor connected in series to the first transistor between a supply voltage and a voltage reference, the second transistor including a control terminal connected to an output of the bandgap reference voltage circuit; and choosing a value of the load resistor such that a conducting terminal/control terminal voltage of the load transistor varies with temperature to compensate for a variation of a control terminal/conducting terminal voltage of the second transistor as a function of temperature.

23. A method according to claim 22, further comprising choosing characteristics of the first and second transistors to obtain the at least one regulated voltage at an output of the at least one gain stage.

24. A method according to claim 22, wherein the load transistor comprises a bipolar transistor including a base, an emitter and a collector, with the collector and base being connected together so that the load transistor is configured as a diode, and with the emitter being connected to the load resistor.

25. A method according to claim 24, wherein the conducting terminal/control terminal voltage of the load transistor comprises an emitter-base voltage thereof.

26. A method according to claim 22, wherein the first and second transistors each comprises a MOS transistor.

27. A method according to claim 26, wherein the second MOS transistor includes a gate and a source, and wherein the control terminal/conducting terminal voltage of the second MOS transistor comprises a gate-source voltage thereof.

28. A method according to claim 22, wherein the characteristics (η2) of the first and second transistors are defined by the formula:η2≈0.4[(VG2−VEBVT7)−T0(δVEB/δT)]/[IGT(T0)]in which:VG2 is a value of the at least one regulated voltage to be obtained, VEB is the conducting terminal/control terminal voltage of the load transistor, VT7 is a threshold voltage of the second transistor M7, T0 is a reference temperature, IGT is a current supplied by the current generator, and δVEB/δT is a variation of the conducting terminal/control terminal voltage of the load transistor voltage VEB as a function of temperature T.

29. A method according to claim 22, wherein the value of the load resistor (R2) is defined by the formula:R2=0.2[3(VG2−VEB+VT7)+2T0(δVEB/δT)]/[IGT(T0)].

30. A method according to claim 22, wherein the at least one gain stage comprises a plurality of gain stages, with each gain stage providing a respective regulated voltage, the method further comprising:connecting a multiplexing circuit to the plurality of gain stages for receiving the plurality of regulated voltages; and connecting a control circuit to the multiplexing circuit for selecting one of the plurality of regulated voltages for output.

31. A method according to claim 30, further comprising connecting a power amplifier to an output of the multiplexing circuit for amplifying the regulated voltage selected by the control circuit.