The field of the invention is the design of electronic and microelectronic circuits. More precisely, the invention relates to the field of generation of reference electrical voltages used in all applications that require a controlled voltage with very small variations as a function of the temperature, as a function of variations in the power supply voltage or as a function of variations of technological parameters for manufacturing of the various components.
This type of electrical reference voltage is necessary particularly in portable equipment powered by batteries (radiotelephones, portable computers, etc.) and in systems using high performance complex electronic circuits and more generally in integrated circuits based on microcontrollers.
Two current sources with opposite dependences on temperature are usually used to generate a reference voltage that is as little dependent as possible on temperature variations:
Such a reference voltage source based on PTAT/CPTAT currents is also described in an article published in the IEEE Journal of Solid-State Circuits in May 1999 entitled “A CMOS Bandgap Reference Circuit with Sub-1-V Operation” by Hiromeri Bomba et al.
More precisely, the positive temperature coefficient of the PTAT current source is usually obtained from a voltage difference between two diodes, or between two base-emitter junctions of forward biased bipolar transistors, and the negative temperature coefficient of the CPTAT current source is obtained from the voltage at the terminals of a diode or the base-emitter junction of a forward biased bipolar transistor.
Conventionally, cascading or regulation is used to make the generated reference voltage independent of variations in the power supply voltage.
French patent application No. FR 2842317 entitled “Source de tension de référence, capteur de température, détecteur de seuil de température, puce et systéme correspondent” (Reference voltage source, temperature sensor, temperature threshold detector, chip and corresponding system), in the name of the same Applicant as this patent application, gives a more detailed description of an example device for generation of a reference voltage according to prior art.
A first operational amplifier 14 biases the bipolar components of the circuit and generates a current proportional to the temperature (PTAT), the value of which may be adjusted by varying the value of the resistance R1.
A second operational amplifier 15 is used in a follower circuit, and is connected to the smallest bipolar transistor Q1: it is used to generate a current conversely proportional to the temperature (CPTAT), the value of which can be adjusted by varying the resistance R2.
These two currents, one proportional to temperature (PTAT) and the other conversely proportional to temperature (CPTAT) respectively are added in a third resistance Rs 13 to generate an adjustable voltage that can be made independent of the temperature by adjustment of the PTAT and CPTAT currents.
This type of circuit also includes a current source not shown in
The device in
For each bipolar transistor Q1 and Q2, there is a base-emitter voltage
(namely
for Q1, and
for Q2, where IE and IS denote the emitter and saturation currents of transistors Q1 and Q2 respectively, and T is the absolute temperature.
When the input voltages at points A and B in the operational amplifier 14 are identical, namely v(A)=v(B), ΔVBE=VBE1−VBE2 can be expressed in the form
where currents IS2 and IS1 are proportional to the size of the emitters of the bipolar transistors Q2 and Q1.
The following expressions are then deduced:
which is proportional to the absolute temperature T, where k and q are constant, and where S2/S1 denotes the ratio of the surfaces of emitters of the two bipolar transistors Q2 and Q1, and
that is conversely proportional to the temperature T.
The reference voltage VREF is then expressed as follows
The first term
in this equation is proportional to the absolute temperature T, and the second term
is conversely proportional to T. Thus, if the absolute value of the temperature coefficients in each of these two terms can be made equal, the voltage VREF produced at the output from the device in
The current source (that includes a starting circuit that is active on power up and outputs the biasing current for the two operational amplifiers 14 and 15) that is not shown in
It has also been proposed to add an additional variable resistance to existing reference voltage generation devices in series with the PTAT generator, to adjust the value of the current proportional to the temperature output by the generator. This is called “trimming”.
Reference voltage generation devices according to prior art like those for example illustrated in
One disadvantage of these components is that their value can vary by about plus or minus 20% as a function of the parameters of the technology from which they are made (typically as a function of the silicon wafer on which they are made). Therefore, these components have a poor absolute precision, which has the effect of inducing a dispersion of the reference voltage produced at the output, both as a function of the temperature and as a function of the technological parameters (process variations).
Therefore, one disadvantage of the “Bandgap” type techniques for the generation of reference voltages according to prior art is the inaccuracy of the generated voltage, depending on variations of the temperature and technological parameters.
The addition of an additional variable resistance in series with the PTAT generator (trimming resistance) provides a means of adjusting the value of the current proportional to the temperature output by the generator, but the resistance has to be adjusted whenever any process variations occur.
Therefore, it is necessary to act on each device to adjust the value of the trimming resistance as a function of process variations, which is particularly tedious.
The main purpose of the invention is to overcome these disadvantages according to prior art.
More precisely, one purpose of the invention is to provide a technique for generation of an electrical reference voltage that has a better precision than reference voltages generated using techniques according to prior art. One particular purpose of the invention is to improve the precision of the reference voltage generated with regard to temperature variations and/or technological parameters for manufacturing of components (particularly when using polysilicon resistance type components).
In other words, the purpose of the invention is to provide a technique for generating a reference electrical voltage to reduce the dispersion of the output voltage from a “bandgap” type device.
Another purpose of the invention is to propose such a technique that is simple and inexpensive to implement, and which does not require adjustment of specific components.
In particular, the purpose of the invention is to provide such a technique that will limit actions necessary to adjust the values of components after they have been assembled, when their operating conditions change.
Another purpose of the invention is to propose such a technique that does not significantly increase the complexity of reference voltage generation devices compared with prior art.
Another purpose of the invention is to provide such a technique that is suitable for devices for generation of low electrical reference voltages for which operation is based on summation of currents.
These objectives, and others that will become clear later, are achieved using a device for generation of a reference electrical voltage comprising a first current generator outputting a current proportional to temperature and a second current generator outputting a current conversely proportional to temperature, and means of summating of the said currents so as to obtain a voltage independent of the said temperature, the said first current generator comprising at least one operational amplifier and two branches in parallel, a first branch comprising a first current source controlled by the operational amplifier, and a first bipolar transistor, and a second branch comprising a second current source controlled by the operational amplifier, a first resistance and a second bipolar transistor.
According to the invention, this type of device for generation of an electrical reference voltage comprises means of reducing dependence of current circulating in the said first branch on the value of the said first resistance, the said reduction means comprising at least one second resistance with a non-adjustable value.
Thus, the invention is based on a quite new and inventive approach to the generation of a reference voltage, independent of temperature and variations in processes for manufacturing components used to make such a device. The invention proposes a technique for generation of a reference voltage that has better precision than techniques according to prior art due to a reduction in sensitivity to the values of the resistances used.
This technique is based on a “bandgap” type device based on operational amplifiers.
In particular, this type of bandgap provides a means of supplying an adjustable output voltage between 0 V and the power supply voltage. It can also operate at voltages less than 1 V.
The recent introduction of means for reducing dependence on the value of resistances makes it possible to eliminate the strong dispersion of the reference voltage generated at the output induced by variations of plus or minus 20% in the values of resistances (for example polysilicon resistances) as a function of technological parameters used for their manufacture.
If this second resistance is made using the same technological process as the first, the variation of its value will thus be similar to the variation of the first resistance, which will enable fine compensation of dependence on the value of the first resistance to the current circulating in the first branch.
In particular, the use of such a resistance with a non-adjustable value provides a means of eliminating problems related to adjustment of components, since the value of the resistance is adjusted when it is integrated into the reference voltage generation device.
The invention thus eliminates the component adjustment step that was necessary according to prior art as soon as any change in the resistivity occurred.
Advantageously, the said reduction means act so as to increase the current circulating in the said first branch when the resistivity of the said first resistance is higher than a reference value, and to reduce this current when the resistivity of the said first resistance is smaller than a reference value.
Thus, a relative balance is maintained between currents generated by the first current generator and the second current generator in the device when technological parameters change, which reduces dispersion of the reference voltage generated at the output.
Advantageously, the said second resistance is placed on the said second branch, on a link made between the said first and second current sources.
This second resistance is thus placed in series with the bipolar transistor in the second branch.
In particular, the second resistance can be mounted in series between the second current source and a power supply to the voltage generation device.
Preferably, the said second resistance is chosen such that ratio of the said currents proportional and conversely proportional to the temperature remain within a predetermined interval of values when the value of the said first resistance varies.
This interval of values is as narrow as possible, to assure that the ratio of the currents generated by each of the first and second generators are as constant as possible, as a function of the variation of technological parameters.
Advantageously, the first and second resistances are made using the same technology, so that they have the same behaviour as a function of variations in operating conditions of the said device.
In particular, the said first and second resistances may be polysilicon resistances made on the same wafer.
The invention also relates to an integrated electronic circuit comprising a device for generation of a reference electrical voltage comprising a first current generator outputting a current proportional to the temperature and a second current generator outputting a current conversely proportional to the temperature, and means of summating the said currents so as to obtain a voltage independent of the said temperature. The first current generator comprises at least one operational amplifier and two branches in parallel, namely a first branch comprising a first current source controlled by the operational amplifier, and a first bipolar transistor, and a second branch comprising a second current source controlled by the operational amplifier, a first resistance and a second bipolar transistor.
Such a generation device comprises means of reducing dependence of the current circulating in the said first branch to the value of the said first resistance, the said reduction means comprising at least one second resistance with a non-adjustable value.
Other characteristics and advantages of the invention will become clearer after reading the following description of a preferred embodiment given as a simple illustrative and non-limitative example, and the attached drawings among which:
The main purpose of the invention is based on the introduction of means of reducing dependence on the value of resistances of PTAT type current in a reference voltage generation device by summation of currents.
We will present the problem of prior art that the invention is intended to solve, with reference to
To achieve this,
An additional PMOS transistor M0 and a current source 10 have been added to supply current to the bipolar transistors Q1 and Q2.
The voltages at points in_p and in_m, denoted V(in_p) and V(in_m), represent the two input voltages at points A and B of the operational amplifier 14 in
When the value of the resistance R1 decreases (due to variations in technological manufacturing parameters, also called “process variations”), the current
in the second branch 32 increases with a linear variation according to the equation
The regulation point P of the “bandgap” type generation device (in other words the point at which V(in_p)=V(in_m)) then moves from point P to point P′ under the effect of the displacement of the curve representative of the voltage V(in_m) as shown in
The regulating point P corresponds to an initial value of the resistance R1, and the new regulation point P′ corresponds to a reduction of 20% of the value of R1 compared with point P.
At the same time, the current that passes through the resistance R2 of the CPTAT current generator 11 in
Consequently, when the value of the resistance R1 reduces as a function of process variations (typically in a proportion of about 20%), the currents I1 and I2 both increase according to the shift in the regulating point P illustrated in
However, as mentioned above, the current 11 increases linearly with R1 according to a K/R1 law, where K is a constant (since
while the current I2 increases linearly with R2 following a K′/R2 law where K′ is a constant, and logarithmically according to a law in ln(I/R1).
Therefore in the expression
the first term in the equation, in Rs/R1, remains constant when the resistivity of the polysilicon components varies, while the second term varies as a function of the absolute value of the resistivity p of these components.
Therefore, the global effect is twofold:
The inventors of this patent application propose a new type of reference voltage generation device to overcome these problems, one particular embodiment being illustrated in
The circuit in
More precisely, the effect of the resistance R4 may be illustrated from the diagram in
The relation between the values of the currents IM1 and IM2 may be expressed in the following form:
where Vgs
When the value of R1 reduces, the current IM2 passing through the transistor M2 increases as described above with reference to
Note that the resistance R4 has a non-adjustable value. In this case, process variations slightly modify the value of this resistance. There is no need for any action to trim the value of R4.
When R4 reduces, (Vgs
In summary, two opposite effects are obtained:
Therefore, by adjusting the ratio R4/R1, the current IM1 can be kept practically constant when the resistivity of the components changes as a function of variations of technological parameters. The voltage VBE1 then remains constant and the CPTAT current
only depends on R2.
The invention thus proposes a technique for generation of a reference voltage with better precision than is possible with techniques according to prior art, due to a reduction in the sensitivity to values of the resistances and not requiring any readjustment of the value of components if variations occur in the temperature, power supply, etc.
In order to reuse the same notations that were used above with reference to
This is illustrated in
The abscissa of the curves in
As can be seen, the reference voltage VREF output from the “bandgap” device according to the invention is practically independent of process variations: when the resistivity of components in the device changes, the voltage VREF then remains almost constant (curve reference 82). However according to prior art (curve reference 81), the voltage VREF dropped strongly when the resistivity of the components increased.
The abscissa of curves in
As can be seen, the stability of the voltage VREF generated at the output from the “bandgap” device as a function of temperature, is better in the case according to the invention, in which a resistance R4 was added in series in the branch 32 of the current mirror of the PTAT generator 10.
Other embodiments of the invention could be envisaged. In the example presented above with relation to
However, these means could also consist of an additional current injected into a first branch 31 of the PTAT current generator, that would compensate for variations in the current IM1 due to the change in resistivity of R1. In particular, these means could consist of an additional current source proportional to the current I1 placed in parallel on the bipolar transistor Q1.
These means could also consist of one or several additional resistances external to the PTAT current generator circuit 10.
Note also that the use of precise resistance R1, R2 and Rs external to the circuit could also improve the stability of the resistance, but could increase the number of inputs/outputs and also the number of components used, and therefore cause a global increase in the cost of the “bandgap” type device according to the invention.
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04 01753 | Feb 2004 | FR | national |
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