Bandgap reference having power supply ripple rejection

Abstract

A bandgap reference circuit provides an output reference voltage that is generally insensitive to fluctuations in supply voltage, ambient temperature, and output load current. A current regulator establishes an output whose variations are reduced, preferably logarithmically, relative to variations in a supply voltage. A bandgap generator fed by the output current provides an output reference voltage with similarly suppressed variations. A control amplifier biases the bandgap generator to provide a high level common-mode rejection of various error sources.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to bandgap voltage references, and more specifically to bandgap voltage reference circuits with high power supply ripple rejection.

2. Description of the Related Art

In the design of various analog circuits, such as digital to analog converters, voltage regulators, or low drift amplifiers, it is necessary to establish an independent bias reference within the circuit. This stable bias reference can be either a current or a voltage. In most applications, voltage rather than current references are preferred since they are easier to interface with the rest of the circuitry. Voltage references are required to provide a substantially constant output voltage regardless of changes in input voltage, output current, or temperature.

Temperature-compensated bias references are described in a number of publications, including an article by Paul Brokaw, “A Simple Three-Terminal IC Bandgap Reference,” IEEE Journal of Solid-State Circuits, Vol. SC-9, No. 6, December 1974, PP 388-393, and in Grebene, Bipolar and MOS Analog Integrated Circuit Design, John Wiley & Sons, 1984 PP 204-209. In designing temperature-compensated bias references, one starts with a predictable temperature drift, and then finds another predictable temperature source with temperature drift in the opposite direction that can be scaled by a temperature independent scale factor. Then, by proper circuit design, the effects of the two opposite-polarity drifts are made to cancel, resulting in a nominally zero temperature coefficient voltage level.

Three basic temperature drift sources exist that are reasonably predictable and repeatable. The first is the temperature dependence of a bipolar transistor base-emitter voltage drop VBE that exhibits a strong negative temperature coefficient, typically about −2 mV/° C. The second is the temperature dependence of the V BE difference ΔV BE between two transistors, which is proportional to absolute temperature through the thermal voltage V T and thus exhibits a positive temperature coefficient. The third and last temperature drift source is that of the base-emitter voltage of a Zener diode V Z , which is inherently low and positive in polarity.

By scaling one or more of these drift sources and subtracting them from each other, one may achieve the required compensation to provide a temperature independent bias voltage. Most voltage references are generally based on either Zener diodes or bandgap generated voltages. Zener devices characteristically exhibit high power dissipation and poor noise specifications. Bandgap generated voltage references compensate the negative V BE temperature drift with the positive thermal voltage temperature coefficient of V T , with V T equal to kT/q, where k is Boltzmann's constant, T is the absolute temperature in degrees Kelvin and q is the electron charge.

In a simplified model, the output reference voltage V out may be expressed as:

V out =V BE +KV T .  (1)

Since the two terms in the above equation exhibit opposite-polarity temperature drifts, it should be possible, at least in theory, to make V out nominally independent of temperature. A temperature-stabilized output dc level, in which ∂V out /∂T is nominally equal to zero, is realized at an output voltage level on the order of +1.25V, which is very near the bandgap voltage of silicon. The name bandgap reference is derived from this relationship. Numerous variations in the bandgap reference circuitry have been designed, and are discussed for example in the U.S. Pat. Nos. 5,352,973 and 5,291,122 to Audy, assigned to Analog Devices, Inc., the assignee of the present invention.

A voltage reference, in addition to being temperature independent, also ideally applies a substantially constant output voltage irrespective of changes in input voltage supply or output current. These changes create signal noise (ripple) which degrades the overall stability of the voltage output, and should be rejected. The degree of rejection is called the high power supply ripple rejection (PSR). Known bandgap references generally fail to supply a substantially constant output reference voltage.

SUMMARY OF THE INVENTION

The present invention seeks to provide a bandgap reference circuit that is generally insensitive to variations in ambient temperature, input voltage, and output current.

These goals are accomplished by interfacing a current regulator between the voltage supply and a voltage reference circuit. The current regulator generates a regulated output current with reduced fluctuations with respect to variations in the supply voltage and the output load current. The voltage reference circuit operates from the regulated current to produce a stabilized bandgap reference voltage.

The current regulator preferably produces an output current which varies logarithmically with respect to variations in the supply voltage. The voltage reference circuit preferably includes a control amplifier that biases a bandgap generator, and provides a high level common-mode rejection of various error sources in the circuit. The current regulator preferably includes a pnp bipolar transistor that generates a transistor voltage with logarithmically reduced variations compared to the voltage supply.

These and other features and advantages of the invention will be apparent to those skilled in the art from the following detailed description of preferred embodiments, taken together with the accompanying drawings, in which:

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram illustrating a voltage regulator in accordance with the invention;

FIG. 2 is a simplified schematic diagram of a current regulator and a voltage reference that can be used in the voltage regulator of FIG. 1 ; and

FIG. 3 is a more detailed schematic diagram of the voltage reference shown in FIG. 2 .

DETAILED DESCRIPTION OF THE INVENTION

A block diagram of a circuit for implementing the invention is shown in FIG. 1 , which includes a voltage regulator 10 powered from a power supply terminal V+. Terminal V+ typically receives a nominal supply voltage of about 5.0 volts. The voltage regulator 10 comprises a current regulator 20 that delivers a regulated output current to a voltage reference circuit 30 . The regulated current has logarithmically reduced variations compared to changes in the input voltage supply. The reference circuit 30 produces a reference voltage V out to supply a load 40 . The reduced current ripple provided as an input to the voltage reference circuit 30 reduces any variations in V out .

A current regulator 20 that can be used in the circuit of FIG. 1 is illustrated in FIG. 2 . It comprises a current generator that receives a supply voltage from the voltage supply terminal V+ and outputs a regulated current to the voltage reference circuit 30 . The current generator is comprised of a pnp bipolar transistor Q 1 whose emitter is connected to V+ through a resistor R 1 and to its base through another resistor R 2 , with its collector connected to ground. The V+ voltage establishes a variable emitter current I E1 for Q 1 . Large variations in this current are possible due to fluctuations in the voltage supply. The fluctuating current I E1 generates a logarithmically varying voltage V BE1 across the emitter-base junction of the transistor Q 1 , expressed as:

V BE1 =V T *ln ( I E1 /I s ).  (2)

V T represents the thermal voltage of approximately 26 mV at 300 K°), and I s is the transistor saturation current. Since the emitter-base junction of Q 1 and the resistor R 2 are connected in parallel, V BE1 =V R2 , where V R2 is the voltage across R 2 . The logarithmically varying voltage V BE1 in equation (2), divided by the impedance of resistor R 2 , yields the current I R2 as follows:

I R2 =V BE1 /R 2 .   (3)

This logarithmically varying current, with logarithmic reductions in current fluctuations with respect to variations in input voltage supply V+ (except for second order base currents), is output to the voltage reference circuit 30 .

The voltage regulator circuit 30 , includes a bootstrap transistor Q 2 , which has its base connected to the node N 1 at the junction of R 1 , R 2 and the collector of Q 1 , its collector to V+, and its emitter connected to the collector of a buffer output transistor Q 3 . The bootstrap Q 2 prevents collector-base modulations of Q 3 due to supply ripple. The transistor Q 3 has its emitter connected to the output V out of the voltage regulator 10 , and its base to resistor P 2 and the base of Q 1 . The buffer circuit isolates the current I R2 from the effects of load impedance variations at V out . The current regulator 20 therefore outputs to a node N 3 an output current that is substantially equal to I R2 (since the current drawn from N 3 into the base of Q 3 is substantially offset by the base current flowing from N 3 out to Q 1 ), and exhibits fluctuations that are logarithmically reduced relative to variations in the supply voltage V+, as well as insensitive to the output load current.

While the current regulator 20 significantly improves supply ripple rejection, additional improvement comes from a biasing scheme used in the voltage reference circuit 30 , which is also illustrated in FIG. 2 . This circuit includes a well known bandgap generator circuit 31 , which has numerous possible designs as discussed in a number of publications, including U.S. Pat. Nos. 4,475,103 and 4,808,908 to Brokaw and Lewis et al., both assigned to Analog Devices, Inc., the assignee of the present invention. The bandgap reference circuits were developed to provide a stable voltage supply that is insensitive to temperature variations over a wide temperature range. In the example shown, the bandgap generator circuit 31 includes common base connected bipolar npn transistors Q 4 and Q 5 , with the emitter area of Q 5 scaled larger than that of Q 4 by a factor N. A resistor P 3 is connected across the emitters of Q 4 and Q 5 , while a tail resistor R 4 is connected from R 3 to a low return voltage reference, preferably ground. The collectors of Q 4 and Q 5 are also connected to the output of current regulator 20 , through a load 33 . A bandgap reference voltage V ref is provided at node N 2 , which is connected to the bases of transistors Q 4 and Q 5 . With proper resistor trimming, V ref equals the bandgap voltage for the material from which the circuit is formed. The bandgap voltage can vary with the particular process used to fabricate the circuit; for silicon, it is typically in the approximate range of 1.17-1.19V.

By designing the circuit to stabilize V ref at the bandgap voltage, the ultimate voltage output V out may be stabilized at a higher voltage. This is preferably accomolished with a simple resistive voltage divider circuit consisting of resistors R 5 and R 6 connected in series between V out and ground, with node N 2 between R 5 and R 6 . The output voltage V out may be set to any convenient value, and is expressed as:

V out =V ref (1+ R 5 /R 6 ).  (4)

The voltage reference circuit 30 also includes a control amplifier 32 that establishes equal collector voltages for Q 4 and Q 5 . It is comprised of a dual transistor differential amplifier Q 6 /Q 7 that has its non-inverting input (the base of Q 6 ) and its inverting input (the base of Q 7 ) connected to the collectors of Q 4 and Q 5 , respectively. The differential amplifier amplifies any differences between the signals at its input terminals, causing a pnp transistor Q 8 , whose base is connected to the collector of Q 7 , to sink current from current regulator output node N 3 to maintain equal collector voltages for Q 6 /Q 7 , and thereby Q 4 /Q 5 . Process spreads, ambient temperature, and supply ripple are among many factors that may generate collector voltage imbalances between Q 4 and Q 5 .

The control amplifier 32 further includes two current mirror transistor pairs Q 9 -Q 10 and Q 11 -Q 12 to balance any residual imbalances within it. The emitters of Q 9 -Q 10 are connected to each other at node N 3 , their collectors are connected respectively to the collectors of the differential amplifier transistors Q 6 and Q 7 , and the base of Q 9 is shorted to its collector in a diode configuration. Matching transistors Q 9 and Q 10 causes Q 10 to carry a current equal to the collector current of Q 6 (I CQ6 ), ignoring second order base currents. Transistors Q 6 -Q 7 and Q 9 -Q 10 form a differential-to-single-ended converter. Current mirror Q 11 -Q 12 forces the emitter drive current to the Q 6 /Q 7 differential amplifier to equal the collector current sunk by Q 8 . Together with Q 3 , R 5 and R 6 , the control amplifier 32 establises a feedback circuit that drives the collector voltages of Q 6 /Q 7 , and thus the collector voltages of Q 4 /Q 5 , towards equality.

Without the Q 11 /Q 12 mirror, the base-emitter voltage V BE8 for Q 8 would vary logarithmically with changes in I R2 . Any variation in V BE8 generates corresponding variations in the voltages at the collectors of transistors Q 10 and Q 7 , which imbalances the differential amplifier, causing an output error. The differential amplifier becomes unbalanced because the collector voltages of Q 6 and Q 9 no longer equal those of Q 7 and Q 10 . However, the current mirror transistors Q 11 /Q 12 cause I CQ6 to change exactly like I Q8 , generating equal collector voltages for Q 6 -Q 7 . Oscillations that might occur at the Q 8 output of the differential amplifier are mostly dampened by a capacitor C 1 that is connected to the base of Q 8 .

With the arrangement described, the current density through Q 8 differs from that through Q 9 and Q 10 because Q 6 and Q 7 evenly divide the current mirrored in Q 11 . In addition, the base-collector voltage of Q 8 with a non-zero value is unequal to those of Q 9 to Q 12 , which equal zero. FIG. 3 illustrates additional circuitry for reducing these differences. An additional equal area transistor Q 8 A is connected parallel to Q 8 to reduce the current flow through Q 8 by half, making the current densities through Q 6 to Q 10 more equal; doubling the emitter size of Q 8 would have an equivalent effect. Two additional diode-connected transistors Q 13 and Q 14 are connected in series with the common collector connection for Q 8 -Q 8 A to lower the base-collector voltage of Q 8 , setting it approximately equal to the base-collector voltages of Q 9 to Q 12 . A second capacitor C 2 is connected to the base of Q 6 to dampen any oscillation that might occur at the input of the differential amplifier. The described biasing scheme substantially equalizes any current fluctuations in the control amplifier 32 , resulting in a high level common-mode rejection of various possible error sources.

Also shown in the circuit of FIG. 3 are conventional details of both the current mirror 33 and a preferred implementation for Q 5 in the bandgap generator 31 . Mirror 33 is shown as a dual mirror, with a first mirror Q 16 /Q 17 (Q 16 diode-connected) feeding a second mirror Q 17 /Q 18 (Ql 8 diode-connected). The emitter area of Q 5 is effectively quadrupled by implementing it as four equal-area parallel transistors Q 5 A-Q 5 D. Also illustrated is a conventional starter circuit 35 that enables the activation of the entire unit. It is comprised of a transistor Q 19 which has its collector connected to V+, its emitter to node N 3 , and its base to the junction of series connected resistors R 7 and R 8 in a voltage divider circuit between V+ and ground. When a voltage is supplied at V+, half of its value (assuming equal resistive values for R 7 and R 8 ) instantaneously appears at the base of Q 19 to pull-up the Q 19 emitter voltage, activating the rest of the circuit. When the Q 19 emitter voltage rises to less than a diode drop below its base voltage, the base-emitter voltage V BEQ19 becomes zero to shutoff Q 19 . Hence, after the starter circuit 35 activates the entire unit, it automatically shuts itself off.

While illustrative embodiments of the invention have been described, numerous variations and alternate embodiments will occur to those skilled in the art. For example, it may be possible to use voltage controlled transistors such as, for example, field effect transistors (FETs) with appropriate biasing schemes, for some of the illustrated current controlled bipolar junction transistors (BJTs). Such variations and alternate embodiments are contemplated, and can be made without departing from the spirit and scope of the invention as defined in the appended claims.

Claims

1. A voltage regulator that provides a regulated output voltage, comprising:a current regulator that provides a regulated current; a bandgap reference generator that includes first and second transistors which respectively have first and second current terminals that respectively respond to coupled first and second control terminals wherein said bandgap reference generator receives a first portion of said regulated current and generates a reference voltage on said coupled first and second control terminals; a control amplifier that receives a second portion of said regulated current and varies the magnitude of said second portion in response to a voltage difference between said first and second current terminals; and a buffer output circuit that receives a third portion of said regulated current, provides said regulated output voltage and couples a portion of said regulated output voltage to said coupled first and second control terminals.

2. The voltage regulator of claim 1, wherein said current regulator includes:a current resistor that carries said regulated current; and a regulator transistor that has a regulator control terminal and a regulator current terminal that responds to said regulator control terminal wherein said regulator control terminal is coupled to one end of said current resistor and said regulator current terminal is coupled to another end of said current resistor to thereby realize said regulated current.

3. The voltage regulator of claim 1, wherein said first and second transistors respectively have third and fourth current terminals that respectively respond to said coupled first and second control terminals and said bandgap reference generator further includes:a tail resistor coupled to said fourth current terminal; and a second resistor coupled between said third and fourth current terminals.

4. The voltage regulator of claim 1, wherein said bandgap reference generator further includes a current mirror coupled between said first and second current terminals.

5. The voltage regulator of claim 1, wherein said control amplifier includes:a differential pair of transistors that generates a difference current in response to said voltage difference; and a control transistor that varies said magnitude of said second portion in response to said difference current.

6. The voltage regulator of claim 5, wherein said control amplifier further includes a current mirror that provides a tail current to said differential pair in response to said control transistor.

7. The voltage regulator of claim 1, wherein said buffer output circuit includes:a voltage divider; and a buffer transistor that receives a fourth portion of said regulated current and is coupled to said voltage divider to generate said regulated output voltage; and wherein said voltage divider is coupled to provide said portion of said regulated output voltage to said coupled first and second control terminals.

8. A voltage regulator that provides a regulated output voltage, comprising:a current regulator that provides a regulated current; a bandgap reference generator that includes first and second transistors which respectively have first and second current terminals that respectively respond to coupled first and second control terminals wherein said bandgap reference generator receives a first portion of said regulated current and generates a reference voltage on said coupled first and second control terminals; and a feedback circuit that generates said regulated output voltage and couples a portion of said regulated output voltage to said coupled first and second control terminals in response to a difference voltage between said first and second current terminals wherein said feedback circuit includes: a) a control amplifier that receives a first portion of said regulated current and varies said first portion in response to said difference voltage; b) a voltage divider; and c) a buffer transistor that receives a second portion of said regulated current and drives said voltage divider to generate said regulated output voltage across said voltage divider and couple a portion of said regulated output voltage from said voltage divider to said coupled first and second control terminals.

9. The voltage regulator of claim 8, wherein said current regulator includes:a first resistor that carries said regulated current; a regulator transistor having a regulator control terminal coupled to one end of said first resistor and a regulator current terminal that responds to said regulator control terminal coupled to another end of said first resistor; and a second resistor that couples said first resistor to a supply voltage.

10. The voltage regulator of claim 8, wherein said current regulator includes:a regulator transistor having a regulator control terminal and a regulator current terminal that responds to said regulator control terminal wherein said regulator current terminal is coupled to a supply voltage; and a first resistor that is coupled between said regulator control terminal and said regulator current terminal to receive said regulated current.

11. The voltage regulator of claim 8, wherein said control amplifier comprises:a differential amplifier that responds to said voltage difference; and a control transistor that receives a said second portion of said regulated current and varies said magnitude of said second portion in response to said differential amplifier.

12. The voltage regulator of claim 11, wherein said differential amplifier is a differential pair of transistors and said control amplifier further includes a first current mirror that provides a tail current to said differential pair in response to said control transistor.

13. The voltage regulator of claim 12, wherein said control amplifier further comprises a second current mirror that couples a fourth portion of said regulated current to said differential pair.

14. The voltage regulator of claim 12, wherein said voltage divider comprises first and second serially-connected resistors.