CN113721694A

CN113721694A - Self-compensating band gap reference source structure based on curvature function and application thereof

Info

Publication number: CN113721694A
Application number: CN202110898626.9A
Authority: CN
Inventors: 耿莉; 董力; 吕程; 沈云虓
Original assignee: Xian Jiaotong University
Current assignee: Xian Jiaotong University
Priority date: 2021-08-05
Filing date: 2021-08-05
Publication date: 2021-11-30
Anticipated expiration: 2041-08-05
Also published as: CN113721694B

Abstract

The invention discloses a self-compensating band-gap reference source structure based on curvature function and application thereof₁Is connected to a resistor R₁The other end of the first and second transistors is connected with an operational amplifier through a field effect transistor, and the reference voltage V of the band-gap reference source is reduced by utilizing the nonlinearity of the current gain beta of the bipolar transistor_REFThe temperature coefficient of (a). The temperature coefficient of the reference voltage is greatly reduced by utilizing the nonlinearity of the current gain beta of the BJT. Meanwhile, the band gap reference source of the invention uses a self-compensation structure, an additional temperature compensation circuit is not needed, the temperature compensation is directly realized in a core circuit of the band gap reference source, the structure is simple, and the influence brought by process errors is reduced.

Description

Self-compensating band gap reference source structure based on curvature function and application thereof

Technical Field

The invention belongs to the technical field of semiconductor integrated circuits, and particularly relates to a self-compensating band-gap reference source structure based on a curvature function and application thereof.

Background

Bandgap reference sources are commonly used in a variety of analog, digital, and analog-to-digital hybrid circuits to provide high precision voltage biasing. The temperature coefficient is a core index of the bandgap reference source, and the smaller the variation of the output voltage of the bandgap reference source along with the temperature is, the lower the temperature coefficient is.

The basic principle of realizing the low-temperature coefficient band-gap reference source is that a voltage with an approximate zero temperature coefficient is generated by superposing a voltage with a negative temperature coefficient and a voltage with a positive temperature coefficient. Base-emitter voltage V of bipolar transistor in band-gap reference circuit_BEThe negative temperature coefficient is generally-2 to-1.5 mV/DEG C. The base-emitter voltages of two bipolar transistors with different current densities are different, and the voltage difference is delta V_BEHas a positive temperature coefficient. The temperature coefficient is superposed on the base-emitter voltage of the bipolar transistor in a certain proportion for compensation, and then the reference voltage with a lower temperature coefficient can be obtained. In general, V_BEThe function with respect to the temperature T is abbreviated as follows:

wherein, T_rIs the reference temperature. V_G0Which is the bandgap voltage of silicon at 0K, can be considered as a constant. Eta is a process-dependent constant, typically 3.6 to 4.4. From (1), V can be seen_BE(T) the term related to the temperature T is a linear part in the second term and a higher order part in the third term.

A typical bandgap reference source uses first order temperature compensation, i.e., the linear part of the second term in PTAT voltage compensation (1), with a temperature coefficient of tens of ppm/deg.c. With the increasing performance requirements of integrated circuits for bandgap references, the accuracy of output voltages of tens of ppm/c has not been satisfactory. Therefore, the nonlinear term in (1) is offset by high-order temperature compensation, so that a lower temperature coefficient is achieved. The existing high-order temperature compensation technology comprises exponential compensation, second-order curvature compensation, subthreshold compensation, segmented compensation and the like.

The exponential temperature compensation technology utilizes the rule that the current gain beta of the bipolar transistor is exponential along with the temperature change. At a reference output V_REFAnd adding a term which has an exponential relation with the temperature, thereby eliminating the high-order term.

The second-order curvature temperature compensation technology obtains a current I which is secondarily related to the temperature through the drain-source current operation of different MOS tubes_PTAT ²Compensating by adding this current to V_REFAnd eliminating the influence of partial nonlinear terms.

The sub-threshold temperature compensation technology is used for compensating the reference voltage through an MOS tube biased at the sub-threshold. The voltage drop of the resistor is taken as V of the MOS by adding proper current to the resistor_GSMaking MOS work in subthreshold region, the drain of MOS tube is connected to generate V_BEThe magnitude of the extracted current changes nonlinearly with the temperature change, thereby reducing V_REFThe temperature coefficient of (a).

The sectional temperature compensation technology is that the whole temperature interval is divided into a plurality of sections, and temperature compensation of different degrees is carried out in different sectional intervals, so that a very low temperature coefficient is obtained.

The existing temperature compensation technology needs to add an additional compensation circuit, which results in increased circuit complexity, and the effect of temperature compensation is deteriorated due to the influence of process deviation on the additional compensation circuit. Exponential compensation, second order curvature compensation and subthreshold compensation hardly reduce the temperature coefficient below 3 ppm/DEG C. The segmented temperature compensation technology can reduce the temperature coefficient to be very low, but the structure is the most complex, and the influence of process deviation is the largest, so that the actually tested temperature coefficient can hardly reach the simulation level.

Disclosure of Invention

The invention aims to solve the technical problem of providing a self-compensating band gap reference source structure based on a curvature function and application thereof aiming at the defects in the prior art, wherein the temperature coefficient of the reference voltage of the band gap reference source is reduced by utilizing the nonlinearity of the current gain beta of a bipolar transistor, so that the structure is high in precision, low in temperature coefficient and simple and easy.

The invention adopts the following technical scheme:

a self-compensating band-gap reference source structure based on curvature function comprises bipolar transistors, wherein one ends of the bipolar transistors are connected with the ground in common, and the other ends of the bipolar transistors are connected with a resistor R after passing through corresponding resistors respectively₁Is connected to a resistor R₁The other end of the first and second transistors is connected with an operational amplifier through a field effect transistor, and the reference voltage V of the band-gap reference source is reduced by utilizing the nonlinearity of the current gain beta of the bipolar transistor_REFThe temperature coefficient of (a).

Specifically, the bipolar transistor comprises a transistor Q₁And a triode Q₂Resistance R₁One end of (1) is divided into three paths, and one path passes through a resistor mR₂And a triode Q₁Is connected with the collector of the first path through a resistor R₂Are respectively connected with a triode Q₁Base and triode Q₂Is connected with the collector of the triode Q₂Base electrode of the transistor Q₁Emitter and triode Q₂Are connected to common ground.

Further, a triode Q₁The resistance of the branch is triode Q₂The branch resistance is m times.

Further, m is 2.5 to 3.2.

Further, a reference voltage V_REFThe function with temperature T is as follows:

wherein C is a constant, eta is a process factor, delta is a parameter related to the triode current, k is a Boltzmann constant, Q is an electronic charge amount, and m is a triode Q₁The resistance of the branch is triode Q₂Multiple of branch resistance, n being triode Q₁And a triode Q₂Area ratio of (1), beta₀、β₁、β₂Is a constant.

Further, the reference voltage V_REFComprises the following steps:

wherein, V_BE2Is a triode Q₂Base-emitter voltage of.

Further, the method comprisesTriode Q₁And a triode Q₂The area ratio of (a) to (b) is n: 1.

specifically, the source of the field effect transistor is connected with a power supply VDD, the grid of the field effect transistor is connected with the output of the operational amplifier, the drain of the field effect transistor and the resistor R₁Is connected at one end.

Specifically, the temperature coefficient of the self-compensating band gap reference source structure at-40 ℃ to 125 ℃ is 1.8 ppm/DEG C.

The invention has another technical scheme that the self-compensating band-gap reference source structure based on the curvature function can be applied to the integrated circuit with low temperature coefficient.

Compared with the prior art, the invention has at least the following beneficial effects:

the invention relates to a self-compensating band gap reference source structure based on a curvature function, which utilizes a triode Q₂Voltage of base-emitter level V_BENegative temperature characteristic and triode Q₁、Q₂Is a difference of a primary-secondary voltage Δ V_BEGenerates a bandgap reference voltage and couples V through a resistor R1 and a resistor R2_BEAnd Δ V_BEIs regulated by a transistor Q₁And Q₂Non-linearity of the current gain beta versus the reference voltage V_REFCurvature temperature compensation is performed to greatly reduce V_REFThe op-amp clamps the A, B nodes of fig. 1 to equalize the voltage at the nodes.

Further, according to a triode Q₁And a triode Q₂Connection relation of (2), Q₁And Q₂Base current of (2) flows into (R)₁Thereby to the reference voltage V_REFHas an influence on changing V_REFThereby introducing a triode Q into the expression₁And Q₂By the non-linearity of beta, can be applied to V_REFAnd performing high-order temperature compensation.

Further, a triode Q₁The resistance of the branch is triode Q₂The branch resistance is m times, thus changing the current of the two branches, namely changing the triode Q₁And a triode Q₂Current ofDensity ratio, thereby introducing m into the reference voltage V_REFBy adjusting the size of m, V can be optimized_REFThe temperature coefficient of (a).

Further, when m is 2.5 to 3.2, V_REFWith respect to the fact that the derivative of the temperature T is equal to 0 at two temperature points within the interval of-40 ℃ to 125 ℃, V is known from the mathematical relationship_REFThe temperature coefficient of the temperature drift curve is lower as shown in fig. 2(d) with respect to T.

Further in accordance with

The function relation with T can control the influence effect of the parameter beta on the reference voltage by adjusting the magnitude of the variable m, thereby changing

The curve for T. By adjusting the shape of the curve, the reference voltage V can be optimized_REFTemperature characteristics of (1).

Further, a reference voltage V_REFThe expression introduces the variable m and the parameter beta, so that the influence effect of the parameter beta on the reference voltage can be controlled by adjusting the magnitude of the variable m, high-order temperature compensation is carried out on the reference voltage, and the temperature coefficient of the reference voltage is reduced.

Further, a triode Q₁And a triode Q₂The area ratio of (a) to (b) is n: 1, base-emitter voltage V of triode_BEThe current density is related to the collector current density of the transistor, which is related to the area of the transistor. When the current densities of the collectors of the two triodes are different, the base-emitter voltage V of the triodes is_BEAlso, the difference between the base-emitter voltages of the two transistors is DeltaV_BE，ΔV_BEIs a positive temperature coefficient, so that the first-order temperature compensation is carried out on the output voltage.

Furthermore, the source electrode of the field effect transistor is connected with a power supply VDD, and the drain electrode of the field effect transistor is connected with a resistor R₁Is connected such that the field effect transistor is a resistor R₁、R₂And a triode Q₁、Q₂Providing an electric current. Grid connection of field effect transistorThe output of the operational amplifier, therefore, the output of the operational amplifier can adjust the grid voltage of the field effect transistor, thereby controlling the current supplied by the field effect transistor.

Furthermore, the temperature coefficient of the self-compensating band-gap reference source structure based on the curvature function is 1.8 ppm/DEG C at-40-125 ℃, and when the ambient temperature is changed at-40-125 ℃, the change of the output voltage is very small, so that the influence on a high-performance integrated circuit system using the band-gap reference source is very small.

In summary, the present invention greatly reduces the temperature coefficient of the reference voltage by using the nonlinearity of the current gain β of the BJT. Meanwhile, the band gap reference source of the invention uses a self-compensation structure, an additional temperature compensation circuit is not needed, the temperature compensation is directly realized in a core circuit of the band gap reference source, the structure is simple, and the influence brought by process errors is reduced.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

FIG. 1 is a bandgap core circuit diagram for generating a reference voltage;

FIG. 2 is a schematic diagram of the principle of the present invention for temperature self-compensation based on curvature function, wherein (a) is V_REFThe derivative of (a) is a curve of T, and (b) is V without high-order temperature compensation_REFThe temperature drift curve of (c) is V_REFAdding a curvature function to the expression of the derivative, wherein (d) is V_REFTwo poles are generated on a temperature drift curve within the temperature range of-40 to 125 ℃;

fig. 3 is a graph of the temperature drift of the reference voltage of the bandgap reference source.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The invention provides a self-compensating band-gap reference source structure based on a curvature function, which greatly reduces the temperature coefficient of reference voltage by utilizing the nonlinearity of current gain beta of BJT. Meanwhile, the band gap reference source of the invention uses a self-compensation structure, an additional temperature compensation circuit is not needed, the temperature compensation is directly realized in a core circuit of the band gap reference source, the structure is simple, and the influence brought by process errors is reduced.

Referring to fig. 1, a curvature function based self-compensating bandgap reference source structure of the present invention uses high-order curvature temperature compensation and utilizes a triode Q₁And a triode Q₂Current gain beta of the non-linear compensation triode Q₂Voltage of base-emitter level V_BEThe non-linearity of the temperature sensor results in a more ideal temperature drift curve.

Resistance R₁One end of the transistor is connected with the drain electrode of a field effect transistor, the source electrode of the field effect transistor is connected with a power supply VDD, the grid electrode of the field effect transistor is connected with the output of an operational amplifier, the non-inverting input of the operational amplifier is connected with A, the inverting input of the operational amplifier is connected with B, A is a triode Q₁B is a triode Q₂A collector electrode of (a); resistance R₁The other end of the resistor is divided into three paths, one path is through a resistor mR₂And a triode Q₁Is connected with the collector of the first path through a resistor R₂Are respectively connected with a triode Q₁Base and triode Q₂Is connected with the collector of the triode Q₂Base electrode of the transistor Q₁Emitter and triode Q₂Are connected to common ground.

In the structure of the band gap core circuit of fig. 1, a transistor Q₁And a triode Q₂The area ratio of (a) to (b) is n: 1.

in the structure of the band gap core circuit of fig. 1, a transistor Q₁And a triode Q₂Base current of (2) flows through a resistor R₂Thereby introducing a parameter beta into the reference voltage V_REFThis is a prerequisite for the implementation of temperature compensation; and for more effective temperature compensation, the transistor Q is made₁The resistance of the branch is triode Q₂And the size of the branch circuit resistance is m times, so that a parameter m is introduced, and the temperature coefficient is optimized by adjusting the size of m.

The specific principle is as follows:

triode Q₂Voltage of base-emitter level V_BEThe expression for the absolute temperature T is as shown in formula (1), and the logarithmic term in formula (1) is subjected to taylor expansion:

neglecting the part of the absolute temperature T which is more than the second order term, and for V_BE(T) derivation:

referring to fig. 1, in the bandgap reference source structure, if the base currents of the two triodes are not considered, the reference voltage V is_REFThe expression of (a) is:

the derivation is taken for equation (4) and equation (3) is substituted:

wherein C is a constant.

The reference voltage V can be found from the formula (5)_REFThe derivative of (c) with T is shown in FIG. 2(a), and thus V is not subjected to higher order temperature compensation_REFThe temperature drift curve of (A) is shown in FIG. 2(b), in which T is₀Is a reference voltage V_REFZero of the derivative of (c).

The above is the reference voltage V when the base current of the triode is not considered_REFAnalysis of the relation of the derivative thereof to the temperature T; in the bandgap reference core circuit structure shown in fig. 1, the base current will be opposite to the reference voltage V_REFThe effect is generated, and the base current is the key to introduce beta nonlinearity to carry out temperature self-compensation.

The base current versus reference voltage V is analyzed as follows_REFThe specific effect is that, as shown in FIG. 1, consider a triode Q₁And a triode Q₂Base current of (2), then reference voltage V_REFBecomes:

wherein beta is the bipolar triode Q used₁And Q₂Current gain of V_BE2Is a triode Q₂Is also a function of the temperature T:

β＝β₀+β₁T+β₂T² (7)

wherein, beta₀、β₁、β₂Is a constant.

The formula (6) is derived to obtain a reference voltage V_REFAs a function of T:

wherein eta is a process factor, the numeric area is 3.6-4, delta is a parameter related to the current of the triode, k is a Boltzmann constant, Q is the amount of electronic charge, and m is a triode Q₁The resistance of the branch is triode Q₂Multiple of branch resistance, n being triode Q₁And a triode Q₂The area ratio of (a).

As is clear from a comparison of the formula (8) and the formula (5), the reference voltage V in the formula (8)_REFThe expression of the derivative is equivalent to the reference voltage V in the expression (5)_REFAdding a curvature function to the derivative expression, as shown in FIG. 2(c), by controlling the magnitude of the parameter m in FIG. 1, the reference voltage V is adjusted_REFThe two zeros of the derivative are set at reasonable temperatures so that at the reference voltage V_REFTwo poles are generated on the temperature drift curve within the temperature range of-40 to 125 ℃, as shown in FIG. 2(d), the temperature drift curve has a relatively low temperature coefficient.

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of the embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Through simulation, when the value of m is between 2.5 and 3.2, the m is at two temperature points between 40 ℃ below zero and 125 DEG C

Is 0, the reference voltage V_REFThe temperature coefficient of (a) is taken to a minimum.

The band gap reference source designed by the invention adopts a 0.18 mu m CMOS BCD process to carry out circuit design, carries out simulation verification, carries out simulation under cadence software, optimizes the temperature drift curve shape from a figure 2(b) to a figure 2(d) by adjusting the value of m, and reduces the temperature coefficient.

The curve of the output reference voltage of the band gap reference source designed by the invention changing with the temperature is shown in figure 3, and the temperature coefficient reaches 1.8 ppm/DEG C in the temperature range of minus 40-125 ℃.

In summary, the self-compensating bandgap reference source structure based on curvature function of the present invention performs temperature self-compensation based on curvature function on the reference voltage by using the nonlinearity of the current gain β of the BJT, and realizes a temperature coefficient of 1.8 ppm/deg.c within a temperature range of-40 deg.c to 125 deg.c.

The above-mentioned contents are only for illustrating the technical idea of the present invention, and the protection scope of the present invention is not limited thereby, and any modification made on the basis of the technical idea of the present invention falls within the protection scope of the claims of the present invention.

Claims

1. A self-compensating band gap reference source structure based on a curvature function is characterized by comprising bipolar transistors, wherein one ends of the bipolar transistors are connected with the ground in common, and the other ends of the bipolar transistors are respectively connected with a resistor R after passing through corresponding resistors₁Is connected to a resistor R₁The other end of the first and second transistors is connected with an operational amplifier through a field effect transistor, and the reference voltage V of the band-gap reference source is reduced by utilizing the nonlinearity of the current gain beta of the bipolar transistor_REFThe temperature coefficient of (a).

2. The curvature function based self-compensating bandgap reference source structure according to claim 1, wherein the bipolar transistor comprises a triode Q₁And a triode Q₂Resistance R₁One end of (1) is divided into three paths, and one path passes through a resistor mR₂And a triode Q₁Is connected with the collector of the first path through a resistor R₂Are respectively connected with a triode Q₁Base and triode Q₂Is connected with the collector of the triode Q₂Base electrode of the transistor Q₁Emitter and triode Q₂Are connected to common ground.

3. According to claim2 the self-compensating band-gap reference source structure based on the curvature function is characterized in that a triode Q₁The resistance of the branch is triode Q₂The branch resistance is m times.

4. The curvature function-based self-compensating bandgap reference source structure according to claim 3, wherein m is 2.5-3.2.

5. The curvature function-based self-compensating bandgap reference source structure according to claim 2, wherein the reference voltage V is_REFThe function with temperature T is as follows:

6. The curvature function-based self-compensating bandgap reference source structure according to claim 5, wherein the reference voltage V is_REFComprises the following steps:

wherein, V_BE2Is a triode Q₂Base-emitter voltage of.

7. The curvature function based self-compensating bandgap reference source structure of claim 2, wherein the transistor Q is a transistor₁And a triode Q₂The area ratio of (a) to (b) is n: 1.

8. the curvature function-based self-compensating bandgap reference source structure according to claim 1, wherein the source of the FET is connected to a power supply VDD, the gate of the FET is connected to the output of the operational amplifier, the drain of the FET is connected to a resistor R₁Is connected at one end.

9. The curvature function-based self-compensating bandgap reference structure according to any of claims 1 to 8, wherein the temperature coefficient of the self-compensating bandgap reference structure is 1.8ppm/° C from-40 ℃ to 125 ℃.

10. The curvature function based self-compensating bandgap reference source structure of claim 1 can be applied in an integrated circuit.