Comparator for a wide supply voltage range

Miscellaneous active electrical nonlinear devices – circuits – and – Specific signal discriminating without subsequent control – By amplitude

Reexamination Certificate

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Details

C327S089000, C327S563000, C330S260000

Reexamination Certificate

active

06215333

ABSTRACT:

BACKGROUND OF THE INVENTION
Field of the Invention
The present invention relates to a comparator for a wide supply voltage range, in which a source follower is connected downstream of a differential amplifier stage, and a switch closes a feedback loop from the source follower to the differential amplifier stage.
A known use of comparators in electronics is for decoding whether a voltage is larger or smaller than a comparative voltage. Thus, for example, A/D converters based on the principle of successive approximation use multistage comparators as shown schematically in
FIG. 2
in which comparator stages
1
are connected in series via capacitors
2
. During a sample phase, feedback switches
3
, which bridge the individual comparator stages
1
, are closed while an input voltage uin is applied to an input
4
. The offset value for the individual comparator stages
1
and the voltage uin to be measured are stored in the capacitors
2
. In the course of such operation, each individual stage sets its own operating point, while the gain has the value zero because the comparators are bridged by means of the switches
3
.
At a sample instant, all the feedback switches
3
are then opened and a comparative voltage ref is added to the input
4
. Each comparator stage
1
thus amplifies the difference between the voltages uin and ref by a factor of approximately 10. By this means, a small difference at the input
4
encounters a voltage level which can be processed by a downstream logic configuration at an output
5
of the last comparator stage
1
.
Such multistage comparators are described, for example, in IEEE Journal of Solid-State Circuits, Vol. SC-17, No. 6, Dec. 7, 1982; Vol. 27, No. 12, December 1992; and in European patent 0407859 B1.
The individual stages of the comparator shown in
FIG. 2
have hitherto been designed as a differential amplifier stage with a downstream source follower, as shown in FIG.
3
. Thus, in
FIG. 3
a differential amplifier stage
6
is connected at the input and the output to a source follower
7
. In such a circuit configuration, it has been shown that the current which is mirrored in at a reference ground point
8
of the differential amplifier
6
is about 20% larger than the sum of the currents which are impressed by two upper current sources
9
. The remaining 20% of the current is taken by two PMOS diodes
10
.
The structure of the circuit configuration of in
FIG. 3
was developed from a simple differential stage, as shown in FIG.
4
.
The problem of such a differential amplifier is the switches
3
which are used to close a feedback loop for the differential amplifier
6
.
The reason for this is that in A/D converters operating on the principle of successive approximation—explained above with reference to FIG.
2
—it has to be assumed that a positive or negative voltage step change of at least half the comparative voltage ref can occur during the conversion at the input of a comparator stage
1
. With an input voltage uin of VDD=5 V and a comparative voltage ref where Vref=5 V, the comparator must be able to process a step change of 2.5 V at the input
4
. In the case of the differential amplifier
6
, the operating point of a node a
1
or a node q
1
after offset adjustment is at approximately 3.8 V, that is to say the difference between the voltage VDD and the threshold voltage of the PMOS diode
10
. That operating point is held firmly by the PMOS diode
10
.
If a PMOS transistor is used for the switch
3
, a positive voltage step change at the input
4
then becomes the problem because the diodes
100
at the source and drain of the transistor (switch
3
) are turned on, as shown schematically in FIG.
5
. Consequently, charge flows away from a node e
1
after the positive or negative voltage step change until the potential at the node e
1
is smaller than the sum of the voltage VDD and the diode forward voltage. Subsequent comparator decisions therefore become incorrect with successive approximation, so that the conversion result is no longer correct either.
If an NMOS transistor is used for the switch
3
, this problem of a voltage step change does not occur because the diodes
100
can become active only toward ground voltage VSS. This, however, in turn causes problems with a substrate control effect of the NMOS transistor used as the switch
3
.
In such a circuit shown in
FIG. 6
, the semiconductor body (bulk) of the switch
3
is at ground voltage VSS, while the source and drain have the difference between the voltage VDD and a threshold value voltage Vth applied to them. Under these conditions, the switch
3
has a high impedance even if 5 V is applied to its gate terminal.
In order then to solve these switch problems, the source follower
7
has hitherto been connected downstream of the differential amplifier
6
, and the sample phase has been fed back via the two stages, that is to say the differential amplifier
6
and the source follower
7
. As a result of this source follower
7
, the operating point at the node e
1
and/or e
1
q is lower than the voltage at the node a
1
and/or at the node q
1
by the threshold value voltage Vth.
It follows that, if the comparator is to operate satisfactorily within a wide supply voltage range, there is little use for a circuit configuration with a downstream source follower
7
.
In an A/D converter for a cordless telephone (DECT system), battery operation may cause the operating voltage VDD to fluctuate between 2.8 V and 5.4 V. The solution using a downstream source follower
7
cannot be applied satisfactorily here, since the PMOS diode
10
, the source follower and the input transistors of the differential amplifier
6
mean that three transistors are connected between the voltage VDD and the voltage VSS, as shown in FIG.
7
.
With the threshold voltages of approx. 1 V provided by this technology for the individual transistors, as much as 3 V overall are thus required for these transistors. Furthermore, an additional 0.5 V or so for the current source at the reference ground point
8
of the differential amplifier
6
should be available. It is therefore not possible to operate such a comparator at a supply voltage of about 2.8 V.
SUMMARY OF THE INVENTION
It is accordingly an object of the invention to provide a comparator for a wide supply voltage range, which overcomes the above-mentioned disadvantages of the prior art devices and methods of this general type and which requires as little threshold voltage as possible between the operating voltage and the ground voltage in order to set the operating point.
With the foregoing and other objects in view there is provided, in accordance with the invention, a comparator for a wide supply voltage range, comprising:
a differential amplifier stage and a source follower connected downstream of the differential amplifier stage;
a feedback loop connected between the source follower and the differential amplifier stage, and a transistor switch of a given conductivity type connected in the feedback loop from the source follower to the differential amplifier stage; and
a diode of the given conductivity type connected to set an operating point of the differential amplifier stage.
In other words, the objects of the invention are satisfied in that the prior art comparator of the above-mentioned type is provided with a diode which has the same conductivity type as the conductivity type of the transistor which is used as the switch and whereby the diode sets the operating point of the differential amplifier stage.
In accordance with an added feature of the invention, the diode is an NMOS diode. The NMOS diode is expediently connected between the gate of the source follower transistor and the gate of an output transistor in the differential amplifier stage.
In accordance with a concomitant feature of the invention, the diode is connected between the gate of the source follower transistor and a supply voltage.
In order that the substrate control effect does not cause the NMOS transistor (the switch) to have a high impedance in the sample ph

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