EP0936526A2 - Reference voltage generator - Google Patents

Abstract

The reference voltage generator has an inverter (T1,T2) with its output (A) fed back to its input (E) via an operating mode selection device (T3-T7). This allows selective interruption of the connection, and allows a different signal to the output signal to be supplied to the inverter input. The inverter output may be coupled to the inverter input in the normal operating mode with the connection interrupted and a supply voltage potential is coupled to the inverter input in an energy-saving operating mode.

Description

The present invention relates to a reference voltage generator according to the preamble of claim 1, i.e. a reference voltage generator with an inverter, wherein the input terminal of the inverter and the output terminal of the inverter are interconnected.

A reference voltage generator of this type is, for example known from DE 42 15 444 C2.

The reference voltage generator described in this document is part of a circuit for implementing a first voltage level (for example the voltage level of output signals from an ECL circuit) into a second Voltage level (for example, that of a CMOS circuit expected or required voltage level). The reference voltage generator it is up to a reference voltage for the actual level converter.

If, as in DE 42 15 444 C2, the reference voltage generator is part of an integrated circuit, in the simplest case it has, more precisely, the inverter forming it, the structure shown in FIG. 2. That is, it consists of a PMOS transistor T1 and an NMOS transistor T2, which are connected as shown in FIG. The output connection of the inverter implemented in this way lies between the two transistors T1 and T2 and is designated by A in FIG. 2; the input connection coincides with the gate connections of the transistors T1 and T2 and is designated E in FIG. The reference voltage generated by this arrangement is the voltage which can be tapped at the output terminal A of the inverter (and which is fed back to the input terminal E); if the inverter is symmetrical, it is half the supply voltage V _{DD applied to it} .

In the circuit according to DE 42 15 444 C2 between the Reference voltage generator and the level converter a switching element provided by which the connection between the components mentioned if necessary (if the level converter Reference voltage not required) can be interrupted.

When the connection between the reference voltage generator is disconnected and the unit that requires the reference voltage the operation of the reference voltage generator requires less electrical energy than it is when the connection is closed Case is. However, the reference voltage generator needs even if the connection between this and the is broken Unit that requires reference voltage is a non-negligible Energy.

This is understandably a disadvantage, the elimination of which is very desirable.

The present invention is therefore based on the object the reference voltage generator according to the preamble of the claim 1 in such a way that this with little Effort and easily in an (energy-saving) Operating mode is shiftable, in which its energy consumption is reduced to a minimum.

This object is achieved by providing the in characterizing part of claim 1 claimed Features resolved.

Accordingly, the reference voltage generator is with an operating mode setting device provided that designed is the connection between the input port and the Interrupt the output connection of the inverter.

After disconnecting the connection between the input port and the output terminal of the inverter can be connected to the Any other signal be applied as its output signal. The reference voltage generator can therefore by a simple switching process be put into an energy-saving mode.

With appropriate selection of this signal (the size and / or of the time course of the same), the inverter can be converted into one Be put in a state in which he has minimal energy consumption having. Because about the connections made by the switching process is created or separated, only very small currents can flow, which are actuated during the switching process Switch designed for low loads and consequently be very simple.

Because the reference voltage generator is also in the energy-saving mode remain connected to the supply voltage can, switching from normal mode to Energy saving mode and vice versa without special provision Measures very quickly and without swinging in and / or swinging out respectively.

The reference voltage generator according to the invention can therefore be with minimal effort in a simple way in an energy-saving mode offset.

Advantageous developments of the invention are the dependent claims, the following description and the figures.

Figur 1

den Aufbau eines Ausführungsbeispiels des erfindungsgemäßen Referenzspannungsgenerators, und

Figur 2

den Aufbau eines herkömmlichen Referenzspannungsgenerators.

The invention is described below using an exemplary embodiment with reference to the drawing. Show it

Figure 1

the structure of an embodiment of the reference voltage generator according to the invention, and

Figure 2

the construction of a conventional reference voltage generator.

The reference voltage generator described in more detail below is for example as a reference voltage source for a level converter applicable. However, there is no restriction to this; the described reference voltage generator can also work for various other purposes.

The reference voltage generator is in the example under consideration Part of an integrated circuit. Insists on this too however no restriction; the reference voltage generator can also be wholly or partly through discrete components be realized.

The reference voltage generator essentially consists of an inverter, its input terminal and its output terminal are interconnected. The connection of the input port and output connection of the inverter causes Feedback of the signal output at the output connection the input connector, which is the output connector tapped (reference) voltage with a symmetrical structure of the Inverters to half the supply voltage of the inverters sets.

Different from conventional reference voltage generators this is the case with the reference voltage generator considered here the connection between the input connector and the output terminal of the inverter. This enables one to connect to the input terminal of the inverter to create any signal other than its output signal whereby it - with appropriate determination of the at the input connection applied voltage - put into a state in which it has minimal energy consumption.

A possibility for the practical implementation of this novel Reference voltage generator is illustrated in Figure 1.

The reference voltage generator consists of PMOS transistors T1, T3 and T6 and NMOS transistors T2, T4, T5 and T7 which are connected as shown in FIG. 1.

The actual inverter is through the transistors T1 and T2 formed. The output terminal of the inverter is between transistors T1 and T2 and is designated A; the input terminal of the inverter coincides with the gate terminals of the transistors T1 and T2 together and is connected to E designated. In this respect there is agreement between the in the conventional reference voltage generator shown in Figure 2 and the new reference voltage generator shown in FIG. 1.

The novel reference voltage generator shown in FIG. 1 however, additionally includes one through the transistors T3 to T7 operating mode setting device, through which it can be put into an energy-saving mode in which it has minimal energy consumption.

• bilden die Transistoren T3 und T4 ein im Rückkopplungszweig des Inverters liegendes Schaltelement,
• bildet der Transistor T5 ein Schaltelement über welches an den Eingangsanschluß des Inverters ein anderes Signal als dessen Ausgangssignal anlegbar ist, und
• bilden die Transistoren T6 und T7 eine Schaltglied-Ansteuerlogik, durch welche die Transistoren T3, T4 und T5 in Abhängigkeit von einem an einen Standby-Anschluß SB anliegenden Signal angesteuert werden.

Of the transistors T3 to T7 constituting the mode setting device

• the transistors T3 and T4 form a switching element located in the feedback branch of the inverter,
• the transistor T5 forms a switching element via which a signal other than its output signal can be applied to the input terminal of the inverter, and
• The transistors T6 and T7 form a switching element drive logic, by means of which the transistors T3, T4 and T5 are driven as a function of a signal applied to a standby connection SB.

The operating mode setting device is designed to Reference voltage generator in response to a corresponding one Request in the standby or standby mode switch, the requirement being considered Example is that to the standby connection SB a signal signaling the standby request is created becomes; is the signal signaling the standby request in the present case a signal with a high level.

If and for as long as that applied to the standby connection SB Signal has a low level, the transistors T3 conduct, T4 and T6, and turn off transistors T5 and T7.

The conductive state of transistors T3 and T4 causes the switching element thus realized is closed. The most Output terminal of the inverter output signal can thereby fed back via the switching element to the input connection become.

The blocking state of transistor T5 also causes or alternatively to the feedback output signal of the Inverters no other signal applied to the input terminal becomes.

When the level of the standby terminal SB is low The novel reference voltage generator behaves like a signal 1 exactly like the conventional reference voltage generator according to FIG. 2.

This changes when the one connected to the standby connection SB Signal has high level: if and as long as that the standby connection SB applied signal a high level has the transistors T5 and T7, and block the Transistors T3, T4 and T6.

The blocking state of transistors T3 and T4 causes the switching element realized thereby is open. The connection between the input port and the output port of the inverter (the feedback branch) is interrupted and that output from the output terminal of the inverter Signal is no longer fed back to the input connection.

Any input can thereby be connected to the input terminal E of the inverter other voltage are applied. In the present considered Example will be via the now conductive transistor T5 the ground potential at the input terminal E of the inverter created.

Applying the ground potential to the input terminal E of the Inverters causes the transistor T2 to block. This prevents transistors T1 and T2 a cross current flows; in normal operation of the reference voltage generator (if and as long as that on the standby connection applied signal has low level) also flows then when the reference voltage generator from which the reference voltage necessary unit is always one certain current through transistors T1 and T2.

In the standby mode of the reference voltage generator its energy consumption is essentially zero, ie minimal and negligible.

Essentially the same effect occurs when above the transistor 5 or another switching element the other pole the supply voltage of the inverter at its input connection E is created. Then the transistor T1 blocks, but this also prevents that through the transistors T1 and T2 a cross current flows. That is, in this case too the energy consumption of the reference voltage generator essentially zero, also minimal and negligible low.

The potentials of the first pole and the second pole of the supply voltage are potentials whose application to the input connection of the inverter cause its energy consumption becomes minimal. A reduction in energy consumption (compared to the normal operation of the reference voltage generator) however, can also occur when a potential is applied to the input terminal E, that differs from the potentials of the poles of the supply voltage differs. The decisive factor in this context is "only" that the potential applied to the input terminal E at least puts one of the transistors T1 and T2 into a state, in which he blocks or at least a high one Volume resistance has or - more generally expressed - That the potential applied to the input terminal E the Inverters (any part of the same) into one state in which a current flows through it is completely or partially prevented. The states in which the flow of a cross flow is completely or partially prevented are the preferred states, their setting when moving of the reference voltage generator in standby mode or - more generally - an energy-saving mode is sought.

In the example considered, that provided in the feedback branch is used Switching element by two to a so-called transmission gate interconnected transistors formed. Although this has proven to be advantageous in CMOS technology no limitation to this. The switching element can also can be realized practically any other way.

The same applies to the input terminal E of the inverter upstream, formed by the transistor 5 Switching element. This can also be practically implemented in any other way become.

The switching element control logic can also be different than through the Transistors T6 and T7 can be realized.

The described reference voltage generator can be used independently from the details of practical implementation the same can be achieved that this with little effort and easily put into an energy-saving mode is in which its energy consumption to a minimum is reduced.

Claims (7)

Reference voltage generator with an inverter (T1, T2), the input terminal (E) of the inverter and the output terminal (A) of the inverter being connected to one another, characterized by
an operating mode setting device (T3 - T7) which is designed to interrupt the connection between the input terminal and the output terminal of the inverter. Reference voltage generator according to claim 1,
characterized,
that the mode setting device (T3 - T7) is designed to apply a different signal than its output signal to the input terminal (E) of the inverter (T1, T2). Reference voltage generator according to claim 2,
characterized,
that the other signal is a signal by which the inverter (T1, T2) is placed in a state in which the flow of a current through it is completely or partially prevented. Reference voltage generator according to claim 2 or 3,
characterized,
that the other signal has the potential of one of the poles of the supply voltage. Reference voltage generator according to one of claims 2 to 4,
characterized,
that the mode setting device (T3 to T7) is designed to work in response to an externally supplied signal. Reference voltage generator according to claim 5,
characterized,
that the mode setting device (T3 - T7) is designed to interrupt the connection between the input terminal (E) and the output terminal (A) of the inverter (T1, T2) and to apply a different signal to the input terminal of the inverter than its output signal , if and as long as it is signaled by the externally supplied signal that the reference voltage generator is to be operated in an energy-saving mode. Reference voltage generator according to claim 5 or 6,
characterized,
that the mode setting device (T3 to T7) is designed to keep the connection between the input terminal (E) and the output terminal (A) of the inverter (T1, T2) closed and to the input terminal of the inverter no other signal than its output signal apply if and as long as it is signaled by the externally supplied signal that the reference voltage generator is to be operated in the normal operating mode.

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