DE102005032294A1 - Monolithic integrated circuit, has control unit designed such that switches are controlled based on ground potential determined by determination unit when changing section from stand-by mode into active operating mode - Google Patents

Abstract

The circuit has a section (1) provided in stand-by or active operating modes. Switches (5-8) e.g. metal oxide semiconductor transistors, electrically connect a supply line (3) with a supply line (4). A control unit (13) is designed in such a manner that the switches are controlled based on a ground potential determined by a determination unit (12) when changing the section from the stand-by mode into active operating mode. An independent claim is also included for a method of switching an operating mode of a part of a circuit from a stand-by mode into an active operating mode.

Description

The The invention relates to a circuit having a functionality for "waking up" a part of the circuit from a standby mode to an active mode of operation.

In modern circuits is common provided that certain areas of the circuit regardless of other areas of the circuit in a standby mode, i.e. in a stand-by mode, can be operated. Unless during the Operation of the circuit is obvious that this particular Areas at the time or during will not be needed for a foreseeable period of time, these areas will be put into standby mode. When in standby mode areas of the circuit are needed again, can they are returned to the active operating mode. As a result, through This measure achieved a reduction in energy consumption.

Technically becomes the functionality described above in integrated circuits enabled by two electrically isolated from each other ground lines. The first ground line serves to supply the parts of the Circuitry that can be put into standby mode. During the Standby mode is the first ground line from the ground potential decoupled. In contrast, the ground potential is constant at the second ground line. The second ground line leaves with the first ground line via parallel switches connect. As a result, the first ground line with the ground potential be charged.

in the Difference to the ground potential lies the second potential of the Supply voltage, which is generally the positive potential the supply voltage is, usually even during standby mode at the shut down areas of the circuit. These Arrangement requires that the first ground line during the Standby mode on the positive potential of the supply voltage located.

If the parts of the circuit that decoupled from the supply voltage were returned to the active operating mode, i. in the normal mode, to be led back should, the switches between the first ground line and The second ground line gradually closed. The reason that the switches are not closed at the same time but one after the other is that, due to the closing of a switch, the current, the is pulled from the supply voltage source, suddenly rises, which in turn causes that from the supply voltage source supplied supply voltage briefly drops until they get back to their original Value has stabilized. would therefore too many of the switches between the two ground lines closed at the same time As a result, thereby the supply voltage in the short term would fall so far that the components of the circuit that are not in standby mode while, while This time would be insufficiently powered. This would the Operate the circuit and worst case lead to an at least short-circuit failure of the circuit.

Out This reason will be on return in the active operating mode first a small number of switches closed one after the other. After that be for a period of a few hundred nanoseconds no further Switch closed. While During this time, the first ground line reaches the ground potential. Subsequently become the rest Switch closed and the relevant part of the circuit can be operated again in the active operating mode. there contains this second group of switches usually the main number of switches to disposal standing switch.

adversely the approach described above is that the time the for the return the first ground line of the positive potential of the supply voltage needed to the ground potential is only roughly estimated can be, because this time depends on many factors, such as for example, the size of the their connected part of the circuit, the operating conditions, such as. the temperature, as well as the form factor of this circuit section in the layout. In order not to run the risk, the main number of switches too early By default, a waiting period is usually chosen much longer is considered the time the first ground line returns to the ground potential needed. This waiting time is either through a programmable counter or a delay element generated.

task The invention is a circuit with one between the standby mode and to provide the active mode reversible part which at the return in the active operating mode optimal for the particular situation Waiting time can be set. Furthermore, a corresponding method should be specified.

The The invention is based task by the Characteristics of the independent claims 1 and 14 solved. Advantageous developments and refinements of the invention are in the subclaims specified.

Of the inventive circuit has a first part, which in at least two modes of operation can be operated. The user or a control unit can determine if the first part is in a standby mode or an active operating mode. The standby mode is characterized in that the first part of the supply voltage is decoupled, whereas in the active operating mode, the supply voltage is present at the first part.

Of the Circuit further comprises a first line, by means of which the first part of the circuit during the active operating mode is supplied with a supply potential, and a second line, at which the supply potential is applied continuously. The supply potential it represents the one potential of the supply voltage of the circuit dar. The first line and the second line can by means of a switching unit electrically connected to each other.

One The essential idea of the invention is that a determination unit is provided, at least temporarily, the electrical potential the first line determines or estimates in which potential range the potential of the first line is located. A control unit uses the potential value determined by the determination unit, to the switching unit when switching the first part of the circuit from the standby mode to the active mode of operation.

Advantageous the invention is that it allows the switching process, in which the first line is connected to the second line becomes dependent on the electrical potential of the first line and in particular the change of this potential during the Switching process to consider. This measure allows it to find the optimal time, from which a larger number of parallel connections between the first and the second Headed for the constant maintenance of the supply voltage is harmless. As a result, this causes the switching operation from the standby mode possible to the active operating mode done quickly, being sure that the supply voltage not overly influenced by the switching process and thus a proper functioning ensured the circuit is.

According to one preferred embodiment of the circuit according to the invention comprises the switching unit at least one first switch and at least one second switch. The first and second switches are in parallel between the first and the second line switched. Furthermore, when switching the first part of the circuit from the standby mode in the active operating mode, the at least one first switch in time closed before the at least one second switch. It depends Shut down the at least one second switch of the determined by the determining unit Values.

The The preferred embodiment of the invention described above makes it possible to at the beginning of the switching operation by means of the first switch or switches a first connection between the first and the second line to create, over the one relatively less Electricity flowing can. This current flow causes a change in the potential of the first line in the direction of the supply potential, which in the active operating mode is required for the power supply. Once the potential of the first line due to this current flow reaches a certain value or even the supply potential has, can the second switch or switches are closed without causing a collapse to fear the supply voltage is.

simulations have shown that the effective switching time between the two Operating modes by this measure Compared to the switching time in conventional circuits by a factor 5 to 10 shortened becomes.

Preferably the determination unit is designed such that it determines the time determines to which the potential of the first line a given Takes value. In an alternative embodiment, the determination unit determines the time at which the potential of the first line a predetermined Threshold goes through. This Event releases the closing of the at least one second switch.

A further preferred embodiment of the circuit according to the invention provides that a plurality of first switches in parallel between the the first and the second line is arranged. At the beginning of the switching process operating mode, the first switches are closed sequentially, the time intervals between closing the individual first switch are given. This means that at this time the potential of the first line not yet must be considered.

advantageously, Furthermore, a plurality of second switches is provided. Unlike the first switches, the second switches closed in common to a control signal of the control unit.

According to a particularly preferred Aus Design of the circuit according to the invention is the only switching operation, which is determined by the potential of the first line, the closing of the second or the switch. This requires that the determination unit and the control unit can be realized at low cost.

The Supply potential applied to the first line, is advantageously a ground potential of the supply voltage.

Further contains the circuit preferably has a third line connected to the second Potential of the supply voltage is applied. In general it is this is the positive potential VDD of the supply voltage. The third Line is connected to the first part of the circuit according to the invention even while its standby mode connected. This causes the first Lead during of the standby mode to the second potential of the supply voltage is pulled.

The Ground potential of the supply voltage provides in a preferred Embodiment of the invention, the predetermined potential, after according to a is sought above described embodiment of the invention.

Between the first line and the third line are advantageously a weak pull-up resistor switched.

The Determination unit can be implemented in various ways become. The determination unit may be designed, for example, that they are dependent from the potential of the first line as an input value and a given threshold value outputs an output value. If the input value goes through the predetermined threshold, the output value changes. The threshold should be as high as possible close to the ground potential. Accordingly, the output of the determination unit beats as soon as the potential of the first line reaches the ground potential has or is in the vicinity located. As components for Such a determination unit designed for example come Buffer or inverter.

Preferably are all Components of the circuit according to the invention integrated on a common substrate in particular monolithic. The first and second switches are in this case by MOS transistors, which in particular have an n-doped channel realized.

Next the first part of the circuit according to the invention can be a be provided second part of the circuit, its operating state is not must be coupled to the operating state of the first part. This means that the second part is operating in an active mode of operation can be while For example, the first part is in standby mode. The second part of the circuit is connected via the second line Supplied supply potential.

• (a) Bestimmen des Potentials der ersten Leitung; und
• (b) Elektrisches Verbinden der ersten Leitung mit der zweiten Leitung in Abhängigkeit von dem im Schritt (a) ermittelten Potential.

The method according to the invention serves to change the operating mode of a first part of a circuit from a standby mode to an active operating mode. The circuit has a first line and a second line. The first line supplies the first part of the circuit with a supply potential during its active operating mode. The second line is continuously supplied with the supply potential. The method according to the invention comprises the following steps:

• (a) determining the potential of the first line; and
• (b) electrically connecting the first line to the second line as a function of the potential determined in step (a).

The inventive method has the same advantages over conventional methods like the inventive circuit on.

The Invention will now be described by way of example with reference to FIG closer to the drawings explained. In these show:

1 a schematic representation of the power supply of a circuit according to the prior art;

2 a schematic representation of control signals when switching a part of in 1 illustrated circuit from a standby mode in an active mode of operation;

3 a schematic representation of potentials when switching the operating mode according to the 1 and 2 ;

4 a schematic representation of the power supply of a circuit as an embodiment of the circuit according to the invention;

5 a schematic representation of control signals when switching a part of in 4 illustrated circuit from a standby mode in an active mode of operation; and

6 a schematic representation of potentials when switching the operating mode according to the 4 and 5 ,

In 1 a section of a conventional circuit is shown. This circuit has a section 1 which can optionally be placed in a standby mode, if it is not needed at that time. The section 1 is via two supply lines 2 and 3 supplied with the supply voltage. During active operation of the circuit is on the supply line 2 the positive potential VDD of the supply voltage. The ground potential VSS is connected to the supply line 3 only during the active operation of the section 1 at. During the standby mode of the section 1 is the supply line 3 decoupled from the ground potential VSS.

The ground potential VSS becomes the supply line 3 via a supply line 4 made available. On the supply line 4 the ground potential VSS is constant during active operation of the circuit. The two supply lines 3 and 4 can over switch 5 . 6 and 7 as well as a group of switches 8th be electrically connected or separated from each other. The switches 5 to 8th are in a parallel configuration between the supply lines 3 and 4 connected. During active operation of the section 1 are the switches 5 to 8th closed and opened during standby mode.

Furthermore, a control unit 9 provided the switches via their outputs 5 to 8th controls. Each one of the switches 5 to 7 controlled by its own control signal poweron [1], poweron [2] or poweron [3]. The switches 8th are controlled by means of a common control signal poweron [0]. On the input side, the control unit takes 9 a control signal 10 from one in 1 not shown, higher-level control unit.

In the in 2 The diagrams shown are the chronological order in which the switches 5 to 8th on the return from the standby mode to the active mode of operation.

After the control unit 9 by means of the control signal 10 was signaled that the section 1 To return to active mode, it controls the switches 5 to 7 via the control signals poweron [1] to poweron [3] in such a way that they - as in 2 shown - closed in succession with a delay of about 2 ns each. The three times at which the switches 5 . 6 and 7 each closed are in 2 marked with the reference symbols t [1], t [2] and t [3]. Subsequently, a predetermined time period of at least 200 ns elapses until the switches 8th are switched through together with the help of the control signal poweron [0] at the time t [0].

The reasons that follow the procedure described above when closing the switch 5 to 8th underlying, can be determined by the in 3 illustrate the diagram shown. In 3 is through the solid curve 20 the supply voltage, as applied to the circuit, plotted against the time t. The dashed curve 21 gives the temporal behavior of the potential, which is on the supply line 3 is applied. The times t [1], t [2], t [3] and t [0] to which the switches 5 to 8th in each case by means of the control signals poweron [1], poweron [2], poweron [3] or poweron [0] are in 3 also shown.

At the beginning of in 3 shown potential measurement is the section 1 of the circuit in standby mode. Consequently, the switches 5 to 8th opened and the supply line 3 is at the positive potential VDD of the supply voltage. After the switches 5 to 7 or at least one of these switches were closed, due to the current flow generated thereby by the respective closed switch 5 to 7 that the potential of the supply line 3 starting from the positive potential VDD of the supply voltage drops until it has finally reached the ground potential VSS. It is true that the potential of the supply line 3 the faster the more switches are closed, the faster it sinks. Since, as already explained above, the rate at which the potential of the supply line 3 decreases to the ground potential VSS, is not clear from the outset and thus can not be specified exactly when the ground potential VSS is reached, a sufficiently long period of at least 200 ns is waited until after closing the switch 7 also the other switches 8th getting closed. After that is the section 1 of in 1 shown circuit fully operational again.

Furthermore, it is off 3 it can be seen that the supply voltage provided by a supply voltage source occurs each time one of the three switches 5 . 6 or 7 closed, breaks in easily. A regulator in the supply voltage source causes the supply voltage to turn off a short time after each one by closing one of the switches 5 to 7 stabilized burglary and assumes its original value. It must be ensured that the supply voltage remains within the voltage range determined by the lines marked min and max. Otherwise, for example, a too low supply voltage could affect the function of the circuit. These considerations must be particularly important when sizing the switches 5 . 6 and 7 and in the choice of Time intervals between the times t [1], t [2] and t [3] are observed.

In 4 is shown as an embodiment of the invention, a section of a circuit, which in many parts the in 1 shown conventional circuit corresponds. For this reason, corresponding components or sections in the 1 and 4 marked with the same reference numerals.

Unlike the in 1 shown circuit has the in 4 circuit shown a very weak pull-up resistor 11 and one unit 12 on. Further, the control unit 13 for driving the switches 5 to 8th in 4 differently designed than those in 1 shown control unit 9 ,

The pull-up resistor 11 is between the supply lines 2 and 3 connected. To the connection of the pull-up resistor 11 who with the supply line 3 is the input of the unit 12 connected. The output of the unit 12 is with a control input of the control unit 13 connected.

Unlike the in 1 shown circuit is in the in 4 illustrated circuit for waking the section 1 from standby mode, there is no fixed amount of time between closing the switch 7 and the common closing of the switches 8th specified. Rather, the unit serves 12 to that on the supply line 3 to measure applied potential and the control unit 13 to indicate the time at which the supply line 3 the ground potential VSS has reached or to which the potential of the supply line 3 is near the ground potential VSS.

The result of this measure can be determined on the basis of 5 and 6 seen. In the 5 and 6 are the same sizes as in the 2 and 3 are plotted against time t. Out 6 shows that the time t [0], at which the switches 8th be closed, which is precisely the time at which the through the curve 22 characterized potential of the supply line 3 has reached the ground potential VSS. Thereby, in the present embodiment, it is conditional that the in 5 with the reference number 14 marked period of time between the closing of the switch 7 and closing the switch 8th is much shorter than 200 ns.

As a result, the invention thus causes that for waking the section 1 time required from the standby mode is as short as possible and that the supply voltage of the circuit during closing of the between the supply lines 3 and 4 arranged switch 5 to 8th remains within a tolerable range.

For the design of the unit 12 There are different possibilities. Preferably, the unit is 12 designed so that it determines if the potential of the supply line 3 is greater or less than a predetermined threshold. The threshold value is as close as possible to the ground potential VSS. The result of this threshold comparison is at the output of the unit 12 for example, output in the form of a binary signal. So the unit 12 even during a still insufficient power supply of the section 1 is already operational, to its power supply, the positive supply potential VDD and the ground potential VSS of the supply line 4 used. The unit 12 For example, it can be realized by means of an inverter or a buffer, these components each having to have the predetermined low threshold value.

At the in 4 The circuit shown may be a monolithically integrated circuit (IC) on a common substrate. At the counters 5 to 8th they may be MOS transistors, in particular MOS transistors with an n-doped channel. Per mm ² area of the section 1 are of the order of magnitude 4 Switch provided, which are closed sequentially with intervals of 2 ns. In the present embodiment of the invention are 3 switch 5 . 6 and 7 provided because the area of the section 1 about 0.75 mm ² . It is important that when closing the individual switches 5 . 6 and 7 the supply voltage does not fall so low that they are in 6 voltage below "min" (see curve 20 in 6 ).

In the literature, the supply lines 2 and 4 often referred to as "VDD rail" (rail) or "VSS rail". The supply line 3 represents an additional "VSS rail".

Next to the section 1 For example, the circuit may contain other sections whose operating state does not depend on the operating state of the section 1 depends. Thus, at the same time, some sections may be in standby mode while other sections are activated.

Claims (24)

Circuit with - a first part ( 1 ) of the circuit which is optionally in a standby mode or an active operating mode, - a first line ( 3 ), which are used to supply the first part ( 1 ) of the circuit with a supply potential (VSS) during the active operating mode, - a second line ( 4 ), which is supplied with the supply potential (VSS), - a switching unit ( 5 . 6 . 7 . 8th ), which for electrical connection of the first line ( 3 ) with the second line ( 4 ), - a determination unit ( 12 ) for the at least temporary determination of the potential of the first line ( 3 ), and - a control unit ( 13 ) which is designed such that when switching the first part ( 1 ) of the circuit from the standby mode in the active operating mode, the switching unit ( 5 . 6 . 7 . 8th ) as a function of that of the determination unit ( 12 ) determined potential controls. Circuit according to Claim 1, characterized in that - the switching unit has at least one first switch ( 5 . 6 . 7 ) and at least one second switch ( 8th ), and - that the control unit ( 13 ) is configured such that when switching the first part ( 1 ) of the circuit from the standby mode to the active operating mode the at least one first switch ( 5 . 6 . 7 ) before the at least one second switch ( 8th ) and closing the at least one second switch ( 8th ) from that of the determination unit ( 12 ) depends on the determined potential. Circuit according to Claim 2, characterized in that - the determination unit ( 12 ) is designed such that it determines the time (t [0]) at which the potential of the first line ( 3 ) assumes a predetermined value (VSS) or falls below or exceeds a predetermined threshold value, and - that by this point in time (t [0]) closing of the at least one second switch ( 8th ) is determined. Circuit according to Claim 2 or 3, characterized in that - a plurality of first switches ( 5 . 6 . 7 ), and - that the control unit ( 13 ) is configured such that the first switch ( 5 . 6 . 7 ) closes at predetermined intervals in a predetermined order. Circuit according to one or more of Claims 2 to 4, characterized in that - a plurality of second switches ( 8th ), and - that the control unit ( 13 ) is configured to connect the second switches ( 8th ) closes together. Circuit according to one or more of Claims 2 to 5, characterized in that only the closing of the at least one second switch ( 8th ) from that of the determination unit ( 12 ) depends on the determined potential. Circuit according to one or more of the preceding claims, characterized in that - the supply potential with which the second line ( 4 ) is a ground potential (VSS) of the supply voltage. Circuit according to Claim 7, characterized in that - a third line ( 2 ) is provided, which is acted upon by the second potential (VDD) of the supply voltage and fixed to the first part ( 1 ) of the circuit is connected. Circuit according to claims 3 and 7 and in particular according to one or more of claims 4, 5, 6 and 8, thereby in - that the predetermined value is the ground potential (VSS). Circuit according to Claim 8 and in particular according to Claim 9, characterized in that - between the first line ( 3 ) and the third line ( 2 ) a resistor, in particular a pull-up resistor ( 11 ), is switched. Circuit according to one or more of the preceding claims, characterized in that - the determination unit ( 12 ) is designed such that it matches the potential of the first line ( 3 ) compares with a predetermined threshold. Circuit according to one or more of the preceding Claims, thereby in - that the circuit has a common substrate on which the Components of the circuit in particular monolithically integrated are. Circuit according to one or more of the preceding claims, characterized in that - a second part of the circuit is in an active operating mode, while the first part ( 1 ) of the circuit is in the standby mode. Method for changing the operating mode of a first part ( 1 ) of a circuit from a standby mode to an active mode of operation, wherein the circuit - a first line ( 3 ), the first part ( 1 ) of the circuit is supplied with a supply potential (VSS) during the active operating mode, and - a second line ( 4 ), which is supplied with the supply potential (VSS), and wherein the method comprises the following steps: (a) determining the potential of the first line ( 3 ); and (b) electrically connecting the first line ( 3 ) with the second line ( 4 ) as a function of the potential determined in step (a). A method according to claim 14, characterized in that - for electrically connecting the first line ( 3 ) with the second line ( 4 ) at least one first switch ( 5 . 6 . 7 ) and at least one second switch ( 8th ), and - that the at least one first switch ( 5 . 6 . 7 ) before the at least one second switch ( 8th ) and that closing the at least one second switch ( 8th ) depends on the potential determined in step (a). A method according to claim 15, characterized in that - the time (t [0]) is determined, to which the potential of the first line ( 3 ) assumes a predetermined value (VSS) or falls below or exceeds a predetermined threshold value, and - that by this point in time (t [0]) closing of the at least one second switch ( 8th ) is determined. Method according to claim 15 or 16, characterized in that - a plurality of first switches ( 5 . 6 . 7 ), and - that the first switches ( 5 . 6 . 7 ) are closed in a predetermined order with predetermined time intervals. Method according to one or more of claims 15 to 17, characterized in that - a plurality of second switches ( 8th ), and - that the second switches ( 8th ) be closed together. Method according to one or more of claims 15 to 18, characterized in that - only the closing of the at least one second switch ( 8th ) depends on the potential determined in step (a). Method according to one or more of claims 14 to 19, characterized in that - the supply potential with which the second line ( 4 ) is a ground potential (VSS) of the supply voltage. Method according to claim 20, characterized in that - a third line ( 2 ) is provided, which is acted upon by the second potential (VDD) of the supply voltage and fixed to the first part ( 1 ) of the circuit is connected. Process according to claims 16 and 20 and in particular according to one or more of claims 17, 18, 19 and 21, thereby in - that the predetermined value is the ground potential (VSS). Method according to one or more of claims 14 to 22 characterized, - that the circuit is on common substrate on which the components of the circuit in particular monolithically integrated. Method according to one or more of claims 14 to 22, characterized in that - a second part of the circuit is in an active operating mode, while the first part ( 1 ) of the circuit is in the standby mode.