DE10109220A1 - Integrated circuit with a supporting capacity - Google Patents

Abstract

The invention relates to an integrated circuit comprising a supply potential connection, a reference potential connection and an energy storage capacitor which is wired up between said two connections. Said energy storage capacitor consists of two conductor tracks or sections of conductor track which are coupled to each other in a capacitive manner.

Description

The invention relates to an integrated circuit with a Supply potential connection and a reference potential close and with a between the supply potential circuit and the reference potential connection connected support box capacity.

In integrated circuits occur during and shortly after egg large current peaks on a clock edge. To prevent that the supply connected to the supply potential connection voltage drops due to the large current peak, two the supply potential connection and the reference potential connected support capacities provided.

Such support capacities can either be external con capacitors provided at the potential connections mentioned be or as internal capacitors in the integrated Circuit be realized. The provision of external support capacities actions required when installing the integrated circuit, for. B. on a circuit board, further processing steps. internal Support capacities require a relatively large area, whereby the integrated circuit on the one hand in its dimensions large and expensive on the other.

The object of the present invention is a Specify generic integrated circuit that is an on reliably prevents the supply voltage from breaking and is easy to manufacture.

This task is accomplished through an integrated circuit, the ge is formed according to the features of claim 1. Preferred embodiments of the invention result from the dependent claims.  

According to the invention it is provided that the support capacity is off two capacitively interconnecting conductor tracks are formed is. A capacitive coupling between the two tracks, which is sufficient to function as a supporting capacity take over is achieved when a ladder track is high Has potential, while the other conductor line has a low potential.

The conductor tracks forming the supporting capacitance can be signal lines lines of the integrated circuit. The ladder tracks can also signal lines of the integrated circuit bedec shields. Since integrated circuits are often already have a shield to spy on data or to prevent the topology of the integrated circuit or at least to make it more difficult to use the Conductor lines of a shield as support capacity. In the case of egg Passive shields are defined with a trace Supply voltage potential or a reference potential be aufschlagt. Two side-by-side or nearby tracks then have a capacitive coupling by the shield to evaluate whether an attack is taking place. The capacity formed between two conductor lines is now according to the invention as the supporting capacity of the integrated circuit used.

It is also conceivable that the conductor tracks vary in height have potential. This also allows the ladder trains a so-called active shield as conductor capacity be used. In contrast to a passive shield with an active shield, the potentials of the conductor tracks varied. However, even with an active shield, the capacitors tive coupling of two adjacent or close to each other Gener conductor lines used for the evaluation of an attack "capacitors" are available here as well Support capacity can be used.  

Unless an integrated circuit does not have one Shield can also use integrated signal lines Circuits are used as support capacitance. Is conceivable For example, use internal bus lines for this.

At least one of the conductor tracks is preferably above each a switch with the supply potential connection and / or with the reference potential connection of the integrated circuit connectable. This configuration allows a conductor track depending on its potential with the supply potential or to connect the reference potential connection. This variant is particularly advantageous if the conductor tracks are a have fluctuating potential. On the other hand, one can Switch between a conductor track and the reference potential and another switch between the other conductor train and the supply potential connection may be provided. This variant is particularly useful if the Supporting capacity forming conductor tracks with a fixed potentiometer al are acted upon.

In one embodiment of the invention, a conductor track is included a means for reloading this conductor. before this line is preferably via a switch both with the supply potential connection and with the Reference potential connection can be connected. It is also a remedy to monitor the charge level of this conductor track see that depending on the charge level of the conductor track the switch controls and connected to this switch electrically connects a potential connection with the conductor track. This procedure ensures that a connection the conductor track with the assigned potential connection only then occurs when the potential difference between the Lei terzug and the potential connection is so low that no voltage drop when closing the switch can kick. In other words, the Lei is first brought to the desired potential,  before its electrical connection with the corresponding bottom tential connection is made.

Based on the following embodiments, the inven tion and its advantages explained further. Show it:

Fig. 1 shows a first embodiment of the inventive integrated circuit SEN,

Fig. 2 shows a second embodiment of the inventive integrated circuit and

Fig. 3 shows an embodiment of the means for monitoring the state of charge.

In the following exemplary embodiments, the same Features marked with the same reference numerals.

Fig. 1 shows a first embodiment of an IC 10 OF INVENTION to the invention. 11 with a circuit block is marked, which contains the actual functionality of the integrated circuit. The circuit block 11 can thus have a memory, a computing unit, registers and the like. The circuit block 11 is on the one hand via a supply potential line 12 with a supply potential connection 14 and on the other hand via a reference potential line 13 with a reference potential connection 15 connected. At the supply potential connection 14 , for example, the supply potential VDD is present, while at the reference potential connection 15, the ground potential VGND is present.

With 20 and 21 , two further circuit blocks are identified, which can represent, for example, the control and reception device of a shield. The circuit blocks 20 , 21 could also present the transmitter and receiver of a bus system re. Two conductor tracks 22 , 23 run between the circuit blocks 20 , 21 by way of example. If it were a shield in this arrangement, the Lei terzüge 22 , 23 would, for example, meander over the circuit block 11 run. The circuit blocks 21 , 22 could then be integrated in the circuit block 11 . For reasons of clarity, the conductor tracks 22 , 23 and the circuit blocks 20 , 21 have been shown adjacent to the circuit block 11 .

If the conductor tracks 22 , 23 have a differently high potential, they have a capacitive coupling to one another. This is indicated in FIG. 1 by the capacitor 24 . The capacitor 24 is not a component of the integrated circuit, but rather is a parasitic element of the integrated circuit.

The present exemplary embodiment according to FIG. 1 shows an arrangement in which the conductor track 22 is supplied with the supply potential VDD and the conductor track 23 is acted upon with a reference potential VGND. The conductor track 22 is connected to the supply potential line 12 via a switch 25 . In a corresponding manner, the conductor track 23 is connected via a switch 26 to the reference potential line 13 . The switches 25 and 26 can be semiconductor switches, e.g. B. MOS Fets han deln that can be controlled via a control line 16 through the circuit block 11 . The switches 25 , 26 can be part of the circuit block 11 .

If the conductor tracks 22 , 23 are opened with a fixed potential, the switches 25 , 26 can be permanently closed GE. The capacitance 24 formed between the conductor tracks 22 , 23 acts as a supporting capacitance in order to prevent a drop in the voltage in the event of large current peaks.

Fig. 2 shows a modification of the first game Ausführungsbei. In contrast to FIG. 2, it is assumed that the conductor tracks 22 , 23 have a varying potential. The variation could be caused, for example, by an inverter located in the circuit block 20, which charges the potential of the conductor strip 23 between the supply potential and the reference potential and in the opposite direction.

Furthermore, a circuit block 30 is provided which is electrically connected to the conductor line 23 via a line 33 . The circuit block 30 represents a means for monitoring the charge state of the conductor line 23. When a threshold is reached, which is just below the supply potential VDD, the switch 25 is closed via the control line 31 , so that the conductor line 23 is connected to the supply line 12 becomes. The switch 26 , which is connected to the reference potential line 13 , however, remains open. The conductor track 23 forms a supporting capacitance with an adjacent line, which is located at or near the reference potential in the exemplary embodiment mentioned. In the vorlie embodiment of FIG. 2, this could be both the conductor 22 or another conductor 27 . To enlarge the capacitance, one of the two conductor tracks 22 , 27 could also be connected to the reference potential line 13 . However, this is not absolutely necessary.

When reloading the conductor strip 23 in the direction of reference potential VGND through the circuit block 20 , both semiconductor switches 25 , 26 must be open. At a threshold that is close to the reference potential VGND, the switch 26 is closed by the means for monitoring the state of charge in the circuit block 30 . The switch 25, however, remains open. A capacitive coupling now takes place between the conductor path 23 lying at reference potential and a conductor path 22 or 27 lying at supply potential.

The signal lines 22 , 23 , 27 need not, as shown in FIGS. 1 and 2, run parallel to one another. The conductor tracks can cross each other or have any other course. If two adjacent conductor track sections have different potential, a capacitive coupling takes place between these conductor track sections, which can serve as a supporting capacitance. In any case, however, it must be ensured that the charge in the conductor tracks or in the conductor track section is sufficient to compensate for voltage fluctuations.

FIG. 3 shows an arrangement known per se from the prior art for monitoring the charge or potential state of a conductor track. For this purpose, the means 30 has two comparators 35 , 36 , the outputs of which are connected to the control lines 31 , 32 . The control lines 31 , 32 are, as can be seen more clearly from FIG. 2, connected to the switches 25 , 26 . If necessary, a driver can be located between the outputs of the comparators 35 , 36 and the switches 25 , 26 .

The inverting input of the comparator 35 , like the non-inverting input of the comparator 36, is acted upon by the potential of the conductor track to be monitored. For this purpose, line 33 establishes a connection to this conductor track.

The non-inverting input of the comparator 35 is acted upon by a potential which is located just above the reference potential VGND. In a corresponding manner, the inverting input of the comparator 36 is acted upon by a potential which is just below the supply voltage VDD.

When one of these set thresholds is exceeded, as described in FIG. 2, the associated switch is closed in order to establish an electrical connection between the monitored conductor line and the desired potential line.

This procedure is only necessary if the power lines forming the Stützka capacity have variable potentials to prevent a voltage drop when closing one of the switches 25 , 26 due to a too large potential difference between the line to be connected and the respective potential line , the means for monitoring the state of charge of this conductor track is provided.

LIST OF REFERENCE NUMBERS

10

integrated circuit

11

circuit block

12

Supply potential line

13

Reference potential line

14

Supply potential connection

15

Reference potential connection

16

control line

20

circuit block

21

circuit block

22

conductor line

23

conductor line

24

capacity

25

switch

26

switch

27

conductor line

30

circuit block

31

control line

32

control line

33

management

35

comparator

36

comparator

Claims (7)

1. Integrated circuit ( 10 ) with a supply potential tialanschluß ( 14 ) and a reference potential connection ( 15 ) and with an between the supply potential connection ( 14 ) and the reference potential connection ( 15 ) connected support capacitance, characterized in that the support capacitance ( 24 ) from two capacitively interconnecting conductor tracks or conductor track sections is formed. 2. Integrated circuit according to claim 1, characterized in that the conductor tracks ( 22 , 23 ) are signal lines of the integrated circuit ( 10 ). 3. Integrated circuit according to claim 1, characterized in that the conductor tracks ( 22 , 23 ) are signal lines of a shield covering the integrated circuit ( 10 ). 4. Integrated circuit according to one of the preceding claims, characterized in that at least one of the conductor tracks ( 22 , 23 ) via a respective switch ( 25 , 26 ) with the supply potential connection ( 14 ) and / or with the reference potential connection ( 15 ) can be connected , 5. Integrated circuit according to one of the preceding claims, characterized in that one of the conductor tracks ( 23 ) is connected to a means for reloading this conductor track ( 23 ). 6. Integrated circuit according to claim 5, characterized in that this conductor track ( 23 ) via a switch ( 25 , 26 ) with the supply potential connection ( 14 ) or the reference potential tial connection ( 15 ) can be connected. 7. Integrated circuit according to claim 5 or 6, characterized in that
a means for monitoring the state of charge ( 30 ) of the conductor ( 23 ) is provided, which controls one of the switches ( 25 , 26 ) depending on the state of charge of the conductor ( 23 ),
and electrically connects the potential connection connected to this switch to the conductor track.