`(12) Patent Application Publication (10) Pub. No.: US 2002/0163364 A1
`
`Majcherczak et al.
`(43) Pub. Date:
`NOV. 7, 2002
`
`US 20020163364A1
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`(54) POWER SUPPLY DETECTION DEVICE
`
`(30)
`
`Foreign Application Priority Data
`
`(75)
`
`Inventors: Sylvain Majcherczak, St. Martin
`d’Heres (FR); Guy Mabboux,
`Chapareillan (FR)
`
`Correspondence Address;
`ALLEN, DYERy DOPPELT, MILBRATH &
`GILCHRIST RA.
`1401 CITRUS CENTER 255 SOUTH ORANGE
`AVENUE
`P.O. BOX 3791
`ORLANDO, FL 32802-3791 (US)
`
`(73) Assignee: STMicroelectronics S.A., Montrouge
`(FR)
`
`(21) App]. No;
`
`10/113,859
`
`(22)
`
`Filed:
`
`Apr. 1, 2002
`
`Apr. 2, 2001
`
`(FR) .............................................. 0104463
`
`Publication Classification
`
`Int. Cl.7 .................................................... H03K 5/153
`(51)
`(52) US. Cl.
`................................................................ 327/78
`
`(57)
`
`ABSTRACT
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`~
`~
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`In an integrated Circuit, a detection dev1ce detects a drop in
`the supply voltage of the core of the integrated circuit or an
`excessively slow build-up of this voltage with respect to a
`supply voltage of the input/output interface circuits of the
`integrated circuit. Outputs of the interface circuits are set to
`a high impedance state by the detection device to minimize
`their power consumption.
`
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`POWER SUPPLY DETECTION DEVICE
`
`FIELD OF THE INVENTION
`
`[0001] The present invention relates to power supplies,
`and more particularly, to a power supply detection device for
`an integrated circuit using at least two power supply volt-
`ages. One power supply voltage is for a core of the inte-
`grated circuit, which is defined by the manufacturing tech-
`nology of the circuit. The other power supply voltage is a
`voltage greater than the power supply voltage for the core,
`and is applied to external interfaces of the integrated circuit
`and to input/output interface circuits within the integrated
`circuit.
`
`BACKGROUND OF THE INVENTION
`
`Integrated circuits with a distinct core supply volt-
`[0002]
`age and a distinct interface supply voltage have appeared
`with new manufacturing technologies used to make low-
`voltage integrated circuits. For these circuits, the core volt-
`age has fallen to 1.8 volts in certain technologies (0.18 y)
`and 1.2 volts in other technologies (0.12 ,u).
`
`[0003] Since these circuits have to be used in systems
`whose power supply voltage is higher,
`the input/output
`interface circuits include a level-matching stage. For the
`transmission of output signals, this level matching is carried
`out by a level translator type selector switch, which receives
`the interface power supply voltage. This switch matches the
`levels of the logic signals received from the core of the
`integrated circuit, and those received from the external
`circuits with which it exchanges data.
`
`Internal control signals are commonly used to
`[0004]
`control the interface circuits. Some of these signals also go
`through the level translators. As for the signals received at
`input from the integrated circuit, they enter with an interface
`voltage level. Their level must therefore be lowered.
`
`It has been observed that these input-output inter-
`[0005]
`face circuits are the site of malfunctions related either to the
`disappearance of the core supply voltage, or to the fact that
`the build-up of this voltage is slower than that of the
`interface supply voltage. In both situations, the level trans-
`lators of the interface circuits do not work properly, and
`malfunctions are seen in the integrated circuit.
`
`It may be recalled that level translators commonly
`[0006]
`have a structure with two arms, each comprising a control
`transistor and a load transistor. One of the control transistors
`
`is controlled by an input logic signal DATA, and the other is
`controlled by the inverse logic signal/DATA.
`
`[0007] When the core supply voltage disappears, the two
`logic voltages DATA and /DATA fall
`to zero. The two
`control transistors are then off. The voltage at an output of
`the translator becomes uncontrollable and dependent on the
`leakage currents in the transistors of the translator, or on a
`contradiction between two logic signals.
`
`[0008] There may then be unnecessary consumption in the
`interface circuit, related to an untimely operation of a part of
`the interface circuits. It would be desirable to detect these
`
`situations in order to force the output signals of the trans-
`lators, and therefore the internal control signals and the
`output signals of the interface circuits, into a defined state.
`
`In particular, the most reliable state for the output signals in
`a core power-off situation is the high impedance state.
`
`[0009] A voltage detection device meeting these require-
`ments must furthermore be adapted to various external
`constraints. The interface supply voltage may indeed have a
`different level depending on the application. For example, it
`may be 2.3 volts to 3.6 volts for interfaces covering typical
`supply voltages of 2.5 volts and 3.5 volts.
`
`[0010] The detector must work properly throughout this
`range of voltage. Furthermore, it should not consume power
`in the stable states. Aelassic detector typically comprises an
`inverter stage controlled by the core supply voltage and
`powered by the interface supply voltage by a diode or series
`of diodes.
`
`the interface supply
`in a given application,
`If,
`[0011]
`voltage is within the lower limit, 2.3 volts in the example,
`there will not be enough voltage to properly power the
`inverter stage because of the drop in voltage in the diodes.
`If, in a given application,
`the interface supply voltage is
`within the higher limit, 2.6 volts in the example, there will
`be, on the contrary, excessive voltage so that the inverter will
`consume power all the time.
`
`SUMMARY OF THE INVENTION
`
`In view of the foregoing background, an object of
`[0012]
`the present invention is to provide a voltage detector that
`detects unnecessary consumption in the interface circuit
`while meeting the above described constraints.
`
`[0013] The invention therefore relates to a device for the
`detection of the level of the core supply voltage of an
`integrated circuit with respect to the level of an interface
`power supply voltage at a higher nominal level, applied as
`a power supply voltage to interface circuits of the integrated
`circuit. For the transmission of input/output signals,
`the
`detection device gives a detection signal applied to the
`interface circuits to set
`their output
`in a state of high
`impedance and minimize their power consumption when the
`level of the core supply voltage is far too low to enable
`operation of the integrated circuit.
`
`this
`[0014] According to one aspect of the invention,
`voltage detection device comprises an input stage compris-
`ing an inverter controlled by the core voltage. The input
`stage is powered with the interface power supply voltage by
`a power supply stage comprising a diode or series of diodes
`and a capacitor.
`
`the capacitor is formec by a
`In one variation,
`[0015]
`P-type MOS transistor that is series-connected between the
`diode or series of diodes and the inverter of the input stage.
`Its gate is then connected to ground and its su3strate
`electrode or well is connected to the interface supply volt-
`age. Its drain and source may also be connected together.
`
`
`
`In another alternative embodiment, the de ection
`[0016]
`device furthermore comprises a buffer type output stage
`comprising an inverter directly powered by the in erface
`power supply voltage and a pull-down transistor for pulling
`the output node of the inverter of the input stage, controlled
`by the signal delivered by the output stage, to the in erface
`power supply voltage.
`
`In another alternative embodiment, the de ection
`[0017]
`device comprises a current loop with gain greater than 1
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`associated with the input stage, and an output stage is
`connected between the interface power supply voltage and
`ground. A first transistor copies the current of the loop, and
`a second translator that is controlled by the core supply
`voltage is series-connected with the first
`transistor. The
`detection signal
`is given by the intermediate connection
`node between the first and second transistors. This output
`signal of the detection device is applied to the input/output
`interface circuits of the integrated circuit, powered by the
`interface supply voltage Vdd3, to set them in a high imped-
`ance state and minimize their consumption.
`
`BRIEF DESCRIPTION OF THE DRAWINGS
`
`[0018] Other features and advantages of the invention are
`described in detail in the following description, given by
`way of an indication that in no way restricts the scope of the
`invention, with reference to the appended drawings of
`which:
`
`[0019] FIGS. 1a and 1b show the basic structure of a
`power supply detection device according to the present
`invention;
`
`[0020] FIG. 2 shows a first alternative embodiment of the
`detection device according to the present invention;
`
`[0021] FIG. 3 shows a second alternative embodiment of
`the detection device according to the present invention;
`
`[0022] FIG. 4 shows an exemplary embodiment of an
`input/output interface circuit of an integrated circuit with a
`core supply voltage and an interface supply voltage accord-
`ing to the present invention;
`
`[0023] FIG. 5 shows an exemplary application of a detec-
`tion signal to an interface circuit according to the present
`invention; and
`
`[0024] FIG. 6 gives a schematic view of an integrated
`circuit comprising a detection device according to the
`present invention to set, if necessary, the circuits in a state
`of high impedance and minimize their power consumption.
`
`DETAILED DESCRIPTION OF THE
`PREFERRED EMBODIMENTS
`
`[0025] FIG. 1a shows a power supply detection device 1
`according to the invention. This circuit outputs a detection
`signal CORE-OFF whose active level indicates that a core
`power—off situation has been detected. It may be recalled that
`the core power-off situation according to the invention
`occurs as a result of either of the following two situations.
`It may occur when the integrated circuit is powered on from
`a core supply voltage Vdd whose voltage buildup is far
`slower then that of the interface supply voltage Vdd3. It may
`also occur during the functional operation of the integrated
`circuit, through the disappearance of the core supply voltage
`Vdd, i.e., a drop in the core supply source.
`
`[0026] A detection system according to the invention can
`be used to detect these power-off situations. According to the
`invention, this device generates a detection signal when the
`level of the core supply voltage is far too low to enable the
`operation of the integrated circuit. An exemplary embodi-
`ment of a device of this kind according to the invention is
`shown in FIG. 1a. It comprises an input stage E1 comprising
`an inverter controlled at input IN by the core supply voltage.
`The inverter of the input stage is typically a CMOS inverter
`
`comprising, in the example, a PMOS transistor M4 and an
`NMOS transistor MS. This input stage is powered with the
`interface power supply voltage Vdd3, by a power supply
`stage E2 comprising a diode or a series of diodes (in the
`example, two diodes D1 and D2), and the capacitor C1.
`
`[0027] As shown in the FIG. 1b, the diodes may be made
`out of MOS transistors whose gate and drain are short-
`circuited. In the example, the first diode D1 is connected to
`the interface power supply voltage, and is formed by a
`PMOS transistor M2. The second diode D2 is connected
`
`between the first diode and the capacitor C1, and is formed
`by an NMOS transistor M3. The capacitor C1 (FIG. 1a) has
`one of its terminals connected to the interface supply voltage
`Vdd. The other terminal is connected to the connection point
`between the diode D2 and the input of the inverter E1. The
`capacitor C1 makes it possible to switch the inverter of the
`input stage for low interface supply voltages, such as for
`voltages of 2.3 V, for example.
`
`[0028] The transistors M2 and M3, which are diode con-
`figured, are sized so that the current that flows through them
`during normal operation remains low as compared with the
`power consumption of the rest of the integrated circuit,
`regardless of the conditions of the temperature and the
`interface power supply voltage. With a setting of this kind,
`in the power-off situations and when there is a low power
`supply voltage, the current that flows across the transistors
`M2 and M3 is also very low, which is in the range of only
`a few tens of pico-amperes (10'12 amperes). This current is
`far too low to power the inverter E1 and build up its voltage
`at output. The capacitor C1 is used to overcome this problem
`of detection at low interface supply voltages.
`
`[0029] During normal operation, the low current that flows
`across the transistors M2 and M3 is stored in the form of
`
`electrical charges in the capacitor. If the core supply voltage
`drops,
`the transistor M4 becomes conductive, and the
`capacitor C1 is discharged through this transistor M4
`towards the output of the inverter E1, and causes the voltage
`to build up at the output of the inverter.
`
`In the other power-oif situation, when the interface
`[0030]
`power supply voltage increases faster than the core power
`supply voltage, the capacitor C1 creates a capacitive cou-
`pling between the interface power supply voltage and the
`source of the transistor M4. This enables the transistor M4
`
`to be placed in a conductive state and enables the transmis-
`sion of the charges through this transistor M4 to the output
`of the inverter.
`
`[0031] FIG. 1b shows a preferred embodiment of the
`capacitor C1.
`In this embodiment,
`the capacitor C1 is
`formed by a P-type MOS transistor M1, whose gate is
`grounded. The drain and source of this transistor are con-
`nected to each other at the connection point between the
`diode D2 (or a series of diodes D1, D2) and the inverter of
`the input stage El.
`
`[0032] The substrate or well electrode of this transistor M1
`is connected to the interface supply voltage Vdd3. One
`variation (not shown) may be obtained by removing the
`drain-source link of the transistor M1. Since the gate of this
`transistor is biased to ground, the drain and source electrodes
`are already connected to each other by the transistor itself,
`since it is conductive. In this case, the source of the transistor
`M1 is connected to the diode D2 (or a series of diodes) and
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`the drain of the transistor M1 is connected to the transistor
`M4 of the inverter of the input stage E1.
`
`In a capacitor C1 formed by a transistor M1 of this
`[0033]
`kind, it is the parasitic source-substrate and drain-substrate
`capacitors that are used. This embodiment using a transistor-
`capacitor M1 is advantageous because it makes use of the
`inverse source-substrate diode current and drain-substrate
`diode current of this transistor which are added to the current
`
`that flows across the series of diodes D1, D2 (M2, M3), thus
`favoring the charging of this transistor-capacitor M1.
`
`[0034] The capacitor C1 may be made with an N-type
`MOS transistor configured as a classic capacitor, whose gate
`would be connected to the interface power supply voltage
`Vdd3 and whose substrate electrode or well, drain and
`source would be connected together to the connection point
`between the diode D2 and the inverter of the input stage El.
`However, in this case, no benefit will be derived from the
`inverse diode currents. A detection device of this kind can
`
`therefore be used for the efficient detection of the power-off
`situations in which the logic signals of the core of the
`integrated circuit no longer have any meaning.
`
`[0035] FIG. 2 shows an alternative embodiment of a
`detection device according to the invention. With the detec-
`tion device shown in FIG. 1a, a detection signal CORE-OFF
`is obtained at output Nin of the inverter. The two levels of
`this signal corresponding to the logic states 0 and 1 are 0 and
`Vdd3—2Vtm, where Vt represents a threshold voltage of the
`MOS transistor.
`
`[0036] This detection circuit is to be applied to interface
`circuits powered by the interface supply voltage Vdd3. In
`particular, if it is sought to turn off a P—type MOS transistor
`in a reliable way, the full level of the supply voltage Vdd3
`must be applied to its gate. The voltage level corresponding
`to the logic state 1 given by the detection device described
`with reference to FIG. 1a does not meet this condition.
`
`[0037] The detection device shown in FIG. 2 thus com-
`prises an output stage E3 following the input stage E1, to
`obtain the desired output levels for the inverse detection
`signal COREOFFD. This output stage E3 comprises an
`inverter IV directly powered by the interface supply voltage
`Vdd3, and a pull—down transistor M6 for pulling the output
`node Nin of the inverter of the input stage to the interface
`power supply voltage Vdd3. This pull-down transistor M6 is
`typically a P-type MOS transistor, controlled at its gate by
`the inverse detection signal COREOFFD given by the inverter
`IV of the output stage E3. This positive pull-down transistor
`M6 enables the proper stabilizing of the detection device. It
`maintains the node Nin at Vdd3, by feedback.
`
`[0038] With the output stage E3, a hysteresis detection is
`obtained with a low threshold of switching from a state of
`the presence of a core power supply to a state of the absence
`of a core power supply, and a high threshold of switching of
`the detection circuit from a state of absence of the core
`
`supply to a state of presence of the core supply. In particular,
`if the output node Nin of the input stage is at Vdd3, then the
`signal IN applied to its input rises sufficiently to force the
`output node Nin downwards, and consequently, cut off the
`pull-down transistor M6. In a practical example, for inte-
`grated circuits using 0.18 M technology with a core supply
`voltage of 1.8 volts, the high threshold may thus be equal to
`0.98 volts and the low threshold may be equal to 0.33 volts.
`
`[0039] FIG. 3 shows another alternative embodiment of a
`detection device according to the invention. This variation
`can be used to give not only the desired voltage level at the
`output, namely 0 and Vdd3, but also a satisfactory operation
`of the detection device, while the difference between the
`minimum and maximum interface supply voltages is greater
`than the nominal level of the core supply voltage Vdd itself.
`
`[0040] This is what happens especially with integrated
`circuits rising 0.12 /1. technology, with a core supply voltage
`that can drop to 0.9 volts, in applications requiring a wide
`range of operation with respect to the interface power supply
`voltage, such as 2.3 volts to 3.6 volts, for example. In this
`case, the detection of the power—off situation cannot rely on
`a detection of an increase in the difference between the core
`
`supply voltage and the interface supply voltage, since this
`voltage difference may be greater in certain cases of normal
`operation than in power-off situations.
`
`In this alternative embodiment, the detection cir-
`[0041]
`cuit comprises, in addition to the input stage E1 and its
`power supply stage E2, a current loop BCP with gain greater
`than 1 associated with the input stage. An output stage E4
`comprising a transistor M11 for copying the current in the
`loop is connected to the interface supply voltage, and a
`transistor M12 is directly controlled by the core supply
`voltage, and is connected to ground.
`
`In the exemplary embodiment shown in FIG. 3, the
`[0042]
`current loop associated with the input stage comprises two
`current mirror structures 2 and 3. The first current mirror
`
`structure comprises a MOS transistor M7 configured as a
`diode (with the gate and drain connected), and is connected
`between the output node Nin of the input stage E1 and
`ground. Asecond MOS transistor MS, has its gate connected
`to the gate of the transistor M7, namely therefore to the node
`Nin.
`
`[0043] The second current mirror structure 3 comprises a
`first MOS transistor M9 configured as a diode (with gate and
`drain connected), and a second MOS transistor M10 con-
`nected between the interface power supply voltage Vdd3
`and the power supply stage E2. The transistor M9 is series
`connected with the transistor M8, between the interface
`power supply voltage Vdd3 and ground. The transistor M9
`has its gate connected to the gate of the second transistor
`M10. The sizes of the transistors of the structures 2 and 3 of
`
`the loop are determined so that they have a gain greater than
`1. They are determined by the usual methods.
`
`[0044] The output stage E4 comprises the transistors M11
`and M12 series connected between the interface power
`supply voltage Vdd3 and ground. The first MOS transistor
`M11 is connected between the interface power supply volt-
`age Vdd3 and the output node Ns which gives the detection
`signal CORE_OFF. It has its gate controlled by the gate of the
`transistor M9 with which it forms a current mirror. Thus, the
`current of the loop is copied by the transistor M11. The
`second MOS transistor M12 is connected between the node
`
`Ns and ground. It has its gate controlled by the core power
`supply voltage Vdd.
`
`[0045] With a detection device of this kind, if the core
`power supply voltage is at its nominal value, 1.2 volts in the
`example, the transistor MS of the input stage E1 is on and
`the output node Nin is pulled to ground. No current flows in
`the loop BCP. Furthermore, the transistor M12 of the output
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`stage E4 is conductive and pulls the node Ns of the stage to
`ground. The current in the stages E1 and E2 is then cut off
`by the transistor M10.
`
`If the core power supply voltage Vdd drops to zero,
`[0046]
`the transistors MS and M12 are off. The current loop is
`active and the transistor M11 of the output stage E4 copies
`the loop current. The node NS (CORE-OFF) is pulled to the
`interface power supply voltage Vdd3.
`
`[0047] With a detection device of this kind, the detection
`is effective even for very nominal values of the power supply
`voltage that are very low when compared with the interface
`power supply voltage. Furthermore, when the power supply
`voltages are at their nominal values, this device does not
`show any consumption (current loop off), and this is advan—
`tageous.
`
`[0048] FIG. 4 shows an exemplary interface circuit for the
`transmission of a piece of data at output,
`to which it is
`possible to apply a detection signal according to the inven—
`tion. This interface circuit comprises a buffer type output
`stage 4. An output stage of this kind is generally a stage with
`N-type and P-type transistors. It is connected between the
`interface power supply voltage Vdd3 and ground. This
`output stage is to be controlled by level signals defined with
`respect to this interface voltage.
`
`[0049] Thus, a level translator, referenced 5 and 6 in the
`figure, provides the control signal for each of the transistors
`of the output stage, from a logic signal DATA, namely the
`piece of data to be transmitted, coming from the core of the
`integrated circuit. Each translator (references 5 and 6) is
`usually followed by an inverter (references 7 and 8) powered
`by the interface power supply voltage Vdd3, so as to
`preserve the same polarity.
`
`In an interface circuit of this kind it is important to
`[0050]
`prevent the transmission of the logic signal DAl'A at the
`output in power-off situations of the core supply voltage Vdd
`as defined in the invention. It is therefore necessary to set the
`output of the interface circuit, namely the output of the
`buffer, in a high impedance state.
`
`It is also necessary to prevent unnecessary con-
`[0051]
`sumption in translators crossed by internal control signals of
`the interface circuit. For this purpose, in power-01f situations
`defined in the invention, it is enough to set the output of the
`translators of the interface circuit in an appropriate state.
`Setting the output of the translators in a determined logic
`state that is independent of the signal to be transmitted, and
`such that the two transistors of the buffer are set in the off
`
`state provides an answer to the different problems of control
`of the interface circuits.
`
`[0052] FIG. 5 shows a level translator in which there are
`provided means controlled by a detection device 1 according
`to the invention. These means are used,
`in a power-off
`situation, to set its output in a determined state, independent
`of the logic signal DATA applied at input. Thus, in addition
`to the usual two-arm structure B1 and B2 of the translator,
`an additional transistor is provided on each arm.
`
`[0053] A first transistor M13 is connected between the
`interface power supply voltage Vdd3 and an output node N1
`of an arm B1, and a second transistor M14 is connected
`between the output node of the other arm B2 and ground. In
`the example, the transistor M13 is a P-type MOS transistor
`
`11
`
`and the transistor M14 is an N-type MOS transistor. Of these
`two transistors, the first one is controlled by the inverse
`detection signal COREOFFD and the second one is controlled
`by the detection signal COREOFF.
`
`[0054] When the detection signal CORE-OFF goes to the
`active state, Vdd3 in the example, the transistor M13 sets the
`output node N1 of the associated arm at Vdd3 while the
`transistor M14 pulls the output node N2 of the other arm to
`zero. If it is sought to pull the nodes N1 and N2 to 0 and
`Vdd3 respectively, it will be enough to reverse the roles of
`the transistors M13 and M14.
`
`[0055] With a detection device according to the invention,
`it is thus possible to control the interface circuit in a sure way
`so that operation of the integrated circuits in their applica-
`tions environment is made more dependable. FIG. 6 gives a
`schematic view of an integrated circuit comprising a detec-
`tion device 1 according to the invention. This detection
`device gives a detection signal CORE-OFF applied to the
`interface circuits 9 powered by the interface power supply
`voltage Vdd3 to set them, in the power-off situation, in a
`state of high impedance.
`That which is claimed is:
`
`1. Adevice for the detection of the level of the core supply
`voltage of an integrated circuit with respect to the level of an
`interface power supply voltage at a higher nominal level,
`applied as a power supply voltage to interface circuits of said
`integrated circuit, for the transmission of input/output sig-
`nals, said detection device giving a detection signal applied
`to said interface circuits to set their output in a state of high
`impedance and minimize their power consumption when the
`level of the core supply voltage is far too low to enable the
`working of the integrated circuit, said detection correspond-
`ing to a power-off situation of the core power supply.
`2. Adetection device according to claim 1, comprising an
`input s age comprising an inverter controlled by the core
`supply voltage, said input stage being powered with the
`interface power supply voltage by a power supply stage
`comprising a diode or series of diodes and a capacitor, these
`diodes 3eing series-connected between said interface power
`supply voltage and the input stage and said capacitor having
`an electrode connected to the input stage, the other electrode
`being cirectly connected to the interface supply voltage.
`3. A detection device according to claim 2, wherein the
`capacitor is formed by a P type MOS transistor, series—
`connec ed between the diode or series of diodes and the
`
`inverter of the input stage, said transistor having its gate
`connec ed to the ground and its substrate electrode or well
`connec ed to the interface supply voltage.
`4. A detection device according to claim 3, wherein said
`MOS transistor has its drain and its source connected
`
`
`
`together.
`5. A detection device according to one of the claims 2 to
`4, furthermore comprising a latch type output stage, com-
`prising an inverter controlled by the output of the input stage
`and directly powered by the interface power supply voltage
`and a pull-down transistor connected between said interface
`supply voltage and said output of the input stage, said
`pull-down transistor being controlled by the signal delivered
`by said inverter.
`6. A dctcction device according to one of the claims 2 to
`4, comprising a current loop with positive gain associated
`with the input stage and an output stage comprising a first
`transistor to copy the current of the loop, series-connected
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`with a second translator controlled by the core supply
`voltage, said first and second transistors being series-con-
`nected between the interface supply voltage and the ground,
`the detection signal being given by the intermediate con-
`nection node between said first and second transistors.
`
`given by said detection device to set an output of said level
`translator in a state determined independently of the logic
`signal applied at input; to set the associated output stage in
`a state of high impedance, in the core supply power-off
`situations.
`
`7. A low—voltage MOS technology integrated circuit com—
`prising a detection device according to any of the claims 1
`to 6, to set input/output interface circuits, powered by the
`interface supply voltage, in high impedance and minimize
`their consumption in the core supply power-off situations.
`8. An integrated circuit according to claim 7, an interface
`circuit comprising at least one level translator powered by
`the interface supply voltage and associated with a buffer type
`data output stage, said translator being used to adapt the
`level of a logic signal coming from the core of the integrated
`circuit, wherein said translator receives a control signal
`
`9. An integrated circuit according to claim 8, said trans—
`lator comprising two arms connected between the interface
`supply voltage and the ground, each arm giving an output
`node, the integrated circuit furthermore comprising a first
`transistor connected between the interface power supply
`voltage and the output node of an arm of the translator and
`a second transistor connected between the output node of the
`other arm of the translator and the ground, to set each of said
`nodes in a determined state.
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