Abstract:
A logic gate comprises a first switch, a second switch, a data network and a keeping circuitry. The first switch is adapted to connect a logic node to a first potential responsive to a transition of an enabling signal. The second switch is adapted to connect the logic node to a second potential via an electrical path responsive to a transition of the enabling signal. The data network is serially connected within the electrical path. The keeping circuitry comprises third and fourth switches serially connected between the logic node and the first potential and being controllable separately from each other, the third switch being adapted to be closed in case a potential on the logic node assumes the first potential and to be opened in case the potential on the logic node assumes the second potential.

Description:
BACKGROUND 
     Exemplary embodiments relate to a logic gate. A logic gate may, for example, be used in dynamic logic circuits and drivers which are recently developed logic circuits designed for high-speed digital electronics, particularly computer CPUs. Logic circuits may comprise logic gates to form combinational logic paths for usage in FPGA, PLD or micro processor circuits of data processing systems. Logic gates may be applied in decoding circuits, for example, address decoding circuits or other circuits performing Boolean operations. Logic gates comprise transistors for realizing logic functions and may be implemented as a semiconductor circuit on a semiconductor wafer. The transistors may be realized in a CMOS semiconductor process. 
     Logic gates being applied in dynamic logic circuits comprise an enable signal for setting the logic gate in a precharged state and a successive evaluation state. The enable signal may be provided by a clock line. Logic gates may be implemented in Domino logic, which is a popular (CMOS-based) implementation of dynamic logic, developed to speed up circuits. 
     Dynamic logic circuits performing a two-phase calculation (precharge phase followed by evaluation phase) should be carefully designed with respect to transistor dimensions. Misadjustments may result in driver conflicts during a transition between the two phases which may cause short-circuit currents damaging the whole circuit. Dimensioning of transistors of dynamic logic circuits with respect to charge balance, chip area, power dissipation and robustness against disturbing influences becomes a risk for the functionality of the circuit, especially at low supply voltages and for high transistor threshold voltages (VTs). For dynamic logic circuits susceptibility to failure is stronger depending on the circuit design tha for static logic circuits. 
     SUMMARY 
     Exemplary embodiments provide a logic gate, comprising a first switch, a second switch, a data network and a keeping circuitry. The first switch is adapted to connect a logic node to a first potential responsive to a transition of an enabling signal from a first logic state to a second logic state. The second switch is adapted to connect the logic node to a second potential via an electrical path responsive to a transition of the enabling signal from the second logic state to the first logic state. The data network is serially connected within the electrical path and is adapted to disable and enable the electrical path responsive to data of a data input. The keeping circuitry comprises third and fourth switches serially connected between the logic node and the first potential and being controllable separately from each other, the third switch being adapted to be closed in case a potential on the logic node assumes the first potential and to be opened in case the potential on the logic node assumes the second potential. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       With reference to the accompanying  FIGS. 1-3 , embodiments of a logic gate will be described. 
         FIG. 1   a  shows a circuit diagram of a logic gate according to an exemplary embodiment; 
         FIG. 1   b  shows a timing diagram of signals associated with the logic gate as depicted in  FIG. 1   a;    
         FIG. 1   c  shows another timing diagram of signals associated with the logic gate as depicted in  FIG. 1   a  according to an exemplary embodiment; 
         FIG. 2  shows a circuit diagram of an address decoding circuit according to an exemplary embodiment; 
         FIG. 3   a  shows a circuit diagram of a logic circuit comprising logic gates and a reference path for generating a switching control signal for the logic gates according to an exemplary embodiment. 
         FIG. 3   b  shows a timing diagram of signals associated with the logic circuit as depicted in  FIG. 3   a  according to an exemplary embodiment; 
         FIG. 4   a  shows a circuit diagram of the logic gate as depicted in  FIG. 1   a , the N-Block comprising a dynamic logic AND gate according to an exemplary embodiment; and 
         FIG. 4   b  shows a circuit diagram of the logic gate as depicted in  FIG. 1   a , the N-Block comprising a dynamic logic OR gate according to an exemplary embodiment. 
     
    
    
     DETAILED DESCRIPTION 
     In  FIG. 1   a  a logic gate according to an exemplary embodiment is depicted. 
     The logic gate  10  comprises a pull-down network  12 , also referred to as “N-block”, a precharge transistor P P , a base transistor N F , also referred to as foot transistor, a keeping circuitry  14  comprising a keeping transistor P K  and a switching transistor P PD . The logic gate  10  further comprises an inverter  16 . 
     The logic gate  10  comprises an enabling input  18  for receiving an enabling signal “enable”, a logic tree input  19  for receiving N logic inputs of the N-Block  12  and an output  20  for providing a data output signal WL. The precharge transistor P P  is connected between a supply node VDD and a logic node  22  and comprises a control terminal which is connected to the enabling input  18  to receive the enabling signal “enable”. The precharge transistor P P  is a p-channel (e.g. MOSFET) transistor. The base transistor N F  is connected between a reference node REF and the N-Block  12  and comprises a control terminal which is connected to the enabling input  18  to receive the enabling signal “enable”. The base transistor N F  is an n-channel (e.g. MOSFET) transistor. 
     The pull-down network  12  is connected between the logic node  22  and the base transistor N F . The pull-down network  12  comprises the logic tree input  19  for receiving the N logic inputs. The pull-down network  12  either pulls the logic node  22  to a logic zero or leaves it at its logic one pre-charged state in response to a Boolean combination of the N logic inputs. 
     The keeping circuitry  14  comprises a series connection of the keeping transistor P K  and the switching transistor P PD . The series connection of keeping transistor P K  and switching transistor P PD  is connected between the supply node VDD and the logic node  22 . Both transistors P K  and P PD  are p-channel (e.g. MOSFET) transistors. A control terminal of the keeping transistor P K  is coupled via the inverter  16  to the logic node  22 . The control terminal of the keeping transistor P K  is connected to the output  20  of the logic gate  10 . A control terminal of the switching transistor P PD  is controlled by a switching control signal “pden”. 
     The central element of the exemplary embodiment is represented by the switching transistor P PD  which is controlled by the switching control signal “pden” “pden”. It is its task to speed up the circuit, to avoid short-circuit currents and to reduce the faulty dimensioning risk as well as susceptibility to failure. 
     To clarify the functionality of the switching transistor P PD , in a first section the logic gate  10  is described without the functionality of the switching transistor P PD . This can be achieved by an always switched-on switching transistor P PD , for example, by setting the switching control signal “pden” “pden” to a logical 0. In a successive section the functionality of the switching transistor P PD  is described by choosing an adequate control of the switching control signal “pden”. 
     In the initial state for the consideration, the enabling signal “enable” is in the state 0 and the output (“WL” node)  20  takes on the logical value 0. The logical states of the inputs  19  in the pull-down network  12  remains without influence on the output  20 . By the effect of the precharge transistor P P  and the keeping transistor P K , the logic node  22 , also referred to as “precharge” node is in the logical precharge state 1, the switching transistor P PD  is always switched-on. 
     Thereupon, valid data are applied to the pull-down network  12 , with the enabling signal “enable” and the output (“WL” node)  20  still being in the state 0. Furthermore, the enabling signal “enable” changes to the state 1. Thus, the precharge transistor P P  is blocked, and the base transistor N F  enables the pull-down network  12 . The “precharge” node  22  takes on the state 1 or 0, corresponding to the occupancy of the inputs  19  in the pull-down network  12 . In the first case, the circuit  10  does not change its state. If the occupancy of the inputs  19  of the pull-down network  12  is, however, such that the pull-down network  12  connects through, the following situation arises. 
     In the series connection comprising the base transistor N F  and the N transistors of the pull-down network  12 , a current flow develops and the charge that was stored on the “precharge” node  22  as well as maybe on the intermediate nodes of the pull-down network  12  flows off to ground REF. At (nearly) the same time, however, the output  20  still is in the state 0, and the keeping transistor P K  thus is conducting. It supplies the “precharge” node  22  with charge. Thus, the keeping transistor P K  drives (“fights”) against the pull-down network  12 . In the path from the supply node VDD via the keeping transistor P K , the pull-down network  12  and the base transistor N F , a short-circuit current flows. This happens until the “precharge” node  22  has reached the state 0 and then the output (“WL” node)  20  the state 1. Only then the keeping transistor P K  is turned off. 
     The prerequisite for the correct functionality of the circuit  10  consists in the fact that the keeping transistor P K  provides less charge than the amount of charge led off to ground by the pull-down network  12  in series with the base transistor N F . This can be the case if the keeping transistor P K  is dimensioned to be sufficiently weak as compared with the transistors of the pull-down network  12 . Thus, there is the possibility of faulty dimensioning of the keeping transistor P K , so that the pull-down network  12 , particularly if it is a series connection of several N (e.g. n-channel) transistors, does not have enough driver strength to overcome the current of the keeping transistor P K . If the pull-down network  12  is not constructed of transistors having great width, the keeping transistor P K  should be adapted by enlarging the transistor length. Here, it should be taken into consideration that such a dimensioning possibly may be produced only with great tolerance for technological reasons. Apart from area losses, this leads to the design risk and reduced robustness. 
     Furthermore, at low supply voltage, the driver capability of the series connection of N transistors decreases more quickly than that of the individual keeping transistor P K . In an otherwise robust circuit, this may lead to malfunction. 
     It is also disadvantageous that the pull-down network  12 , which determines the logic function of the logic gate  10 , is hindered in its driver capability by the keeping transistor P K , since the current through the p-channel keeping transistor P K  drives against the current of the pull-down network  12 , whereby the switching speed of the circuit  10  is affected noticeably. This effect also is more strongly pronounced toward lower supply voltages. 
     If it is attempted to avoid the above mentioned effect, there is the risk of the keeping transistor P K  being designed to be too weak. In turn, this might entail that the “precharge” node  22  is not protected sufficiently against external disturbances. 
     An introduction of the switching transistor P PD  and its control by the switching control signal “pden” overcomes the problems mentioned above. The functionality of the logic gate  10  comprising the switching transistor P PD  is described hereinafter. The “precharge” node  22  is stabilized and secured against coupling and leakage losses, not by a keeping transistor P K , but by a series connection of the keeping transistor P K  and the switching transistor P PD , or the keeping circuitry  14 , respectively. The sequence of the keeping transistor P K  and the switching transistor P PD  in the series-connection is irrelevant here. Also the sequence of the base transistor N F  and the N-Block  12  is irrelevant. 
     The gate terminal of the keeping transistor P K  is attached to the output node  20  for providing the output signal WL. The switching transistor P PD  is connected in series with the keeping transistor P K  into the path between the supply node VDD and the “precharge” node  22  and is controlled by the switching control signal “pden”. 
     The initial state for the consideration corresponds to the one already described above. In the precharge state, the enabling signal enables in the state 0, and the output (“WL” node)  20  takes on the value 0. The switching control signal “pden” here also is logically 0. Now, the “precharge” node  22  is in the precharge state through the effect of the precharge transistor P P , and the series connection of the keeping transistor P K  and the switching transistor P PD . The occupancy of the inputs  19  in the pull-down network  12  remains without effect. 
     Valid data are further applied to the pull-down network  12 , with the enabling signal “enable” as well as the output  20  and the switching control signal “pden” still being in the state 0. 
     Thereupon, the enabling signal “enable” and the switching control signal “pden” (nearly) simultaneously change into the state 1. Alternatively, the switching control signal “pden” may be set into the state 1 earlier. Thus, the precharge transistor P P  and the switching transistor P PD  are blocked, and the base transistor N F  enables the pull-down network  12 . The path between the supply node VDD and the “precharge” node  22  is interrupted by the switching transistor P PD . The “precharge” node  22  takes on the state 1 or 0, corresponding to the occupancy of the inputs  19  in the pull-down network  12 . In the first case, the circuit  10  does not change its state. 
     However, if the occupancy of the inputs  19  of the pull-down network  12  is such that the pull-down network  12  connects through, the following situation arises. 
     In the series connection comprising the base transistor N F  and the N transistors of the pull-down network  12 , a current flow develops, and the charge that was stored on the “precharge” node  22 , as well as maybe on the intermediate nodes of the pull-down network  12  flows off to ground REF. Since the switching transistor P PD  now blocks, the pull-down network  12  only has to drain off the charge stored on the above-mentioned nodes. No additional charge is supplied by the keeping transistor P K , and short-circuit current does not flow either. 
     After the “precharge” node  22  has reached a state corresponding to the input  19  occupancy and function of the pull-down network  12 , the switching control signal “pden” may again change to the state 0. In case the pull-down network  12  does not switch, i.e. the “precharge” signal (at the “precharge” node  22 ) remains logically 1, this change should happen quickly so as not to leave the “precharge” node  22  in a non-driven state for long. 
     Switching on the switching control signal “pden” may be linked directly to the enabling signal “enable”. Switching off may be realized by a delay chain, for example. This is possible in short combinational paths with many gates switching in parallel. 
     If the switching control signal “pden” is controlled correctly, embodiments of the exemplary embodiment offer a series of advantages. There is no risk of the keeping transistor P K  being dimensioned to be too strong (or the pull-down network  12  to be dimensioned too weak). The transistor length of the keeping transistor P K  remains minimal. The speed the pull-down network  12  can work with is increased because less charge has to be drained-off. The functionality of the circuit  10  is not at risk even at low supply voltages. There is no risk of the keeping transistor P K  being dimensioned to be too weak. With this, the susceptibility of the “precharge” node  22  to disturbing influences is reduced. The short-circuit current is avoided, the power consumption drops. Potentially, a reduction in area is achieved, because the width of the transistors in the pull-down network  12  may be dimensioned to be smaller. Additionally, the length of the keeping transistor P K  may be kept minimal. 
     By the inclusion and the control of the switching transistor P PD  a speed-up of the circuit  10 , avoidance of short circuit currents and reduction of the faulty dimensioning risk as well as susceptibility to failures is achieved. 
     Exemplary embodiments may be applied as speed-up and robustness measure also in dynamic logic, for example, Domino circuits. In these families of circuits, the keeping transistor P K  often is required only when circuit  10  is in idle state, because otherwise the time in which the “precharge” node  22  is not driven is very short. Here, the control of the switching transistor P PD  by the switching control signal “pden” is also very simple. The switching transistor P PD  is blocked in the active phase and switched on in the inactive phase. 
     If the keeping transistor P K  is to become effective also in the active phase, the switch-off time instant for the switching control signal “pden” can be derived from the enabling signal “enable”, for example, through delay. 
       FIG. 1   b  shows a set of timing diagrams of signals associated with the logic gate  10  as depicted in  FIG. 1   a . In a first timing diagram ( 1 .) the timing of the enabling signal “enable” is depicted. The enabling signal assumes a first signal state VREF and a second signal state VDD and is a periodical signal. The first signal state VREF corresponds to a precharge phase  100  while the second signal state VDD corresponds to an evaluation phase  101  of the logic gate  10 . 
     A second timing diagram ( 2 .) depicts the timing of the precharge signal “precharge” which is the signal state which the logic node  22  assumes when the logic gate  10  is enabled by the enabling signal “enable”. In a first period  102  of the enabling signal, the pull down-network (N-block)  12  is enabling the discharge of logic node  22  while in a second period  103  of the enabling signal the N-block  12  is disabling the discharge of logic node  22 . During the precharge phase  100  of the first period  102 , the precharge signal is inverse to the enabling signal. When the enabling signal changes from the first state VREF to the second state VDD and the N block  12  is enabling, a driver conflict may occur such that a switching of the precharge signal from VDD to VREF does not occur upon the rising edge of the enabling signal. For a short conflicting time period  104 , a switching of the precharge signal may be non-deterministic as the charge of the logic node  22  is fed to VREF by the N-block  12  while at the same conflicting time period  104 , the keeping transistor P K  is delivering a charge of potential VDD to the logic node  22 . During the second period  103  of the enabling signal, the N-block  12  is disabling the discharge of the logic node  22  such that the precharge signal assumes the second state VDD without a change upon a rising edge of the enabling signal. 
     The third timing diagram ( 3 .) shows the timing behavior of the output signal “WL” of the logic gate  10  which shows the inverse signal state as the precharge signal. 
     A fourth timing diagram ( 4 .) shows the timing of the switching control signal “pden” which holds the first state VREF for the complete representation time depicted in  FIG. 1   b . This corresponds to a permanent through connection of the switching transistor PPD. 
       FIG. 1   c  shows another set of timing diagrams of signals associated with the logic gate  10  as depicted in  FIG. 1   a  according to an exemplary embodiment. A first timing diagram ( 1 .) shows the timing of the enabling signal “enable” which corresponds to the timing of the enabling signal as depicted in  FIG. 1   b.    
     The second timing diagram ( 2 .) shows a timing of a delayed enabling signal “enableDel”. A delay of D is applied to the enabling signal “enable” to obtain the delayed enabling signal “enableDel”. 
     A third timing diagram ( 3 .) shows the timing of the switching control signal “pden” which corresponds to the enabling signal “enable” combined with the inverse of the delayed enabling signal “enableDel” by a logical AND combination. 
     A fourth timing diagram ( 4 .) depicts the timing of the precharge signal during a first period  102  of the enabling signal when the N-block is enabling the discharge of logic node  22  and during a second period  103  of the enabling signal when the N-block is disabling the discharge of logic node  22 . In contrast to the precharge signal depicted in  FIG. 1   b , the precharge signal depicted in  FIG. 1   c  is changing its signal state during the first enabling signal period  102  (N-block is enabling) from VDD to VREF in a deterministic manner upon a rising edge of the enabling signal without a conflicting time period  104 . No driver conflicts can be seen in the timing diagram ( 4 .) of the precharge signal. This results from the control of the switching control signal “pden” which switches off the first potential VDD from the logic node  22  during a transition of the enabling signal from VREF to VDD for the duration of the delay time D. After the delay time D when the discharging process is finished and the precharge signal assumes a logical 0, the switching control signal “pden” switches-on the switching transistor P PD  to allow the keeping transistor P K  taking over control. 
     The delay time D may be dimensioned such that a bridging of the conflicting time period  104  as depicted in  FIG. 1   b  may be achieved. The delay time D may, for example, be greater or equal to the conflicting time period  104 . 
     A fifth timing diagram ( 5 .) depicts the timing of the output signal “WL” which assumes the inverse value of the precharge signal without showing any driver conflicting phases as the output signal “WL” depicted in  FIG. 1   b.    
       FIG. 2  shows an address decoding circuit  30  according to an exemplary embodiment. The address decoding circuit  30  uses a Wired-OR circuitry  32  for generation of a switching control signal “pden” (Rdy, respectively). The address decoding circuit  30  comprises a logic gate  10  which corresponds to the logic gate  10  as described in  FIG. 1  having an enabling input  18  for receiving an enabling signal “enable”, a logic tree input  19  for receiving N logic inputs of the N-block  12  and an output  20  for providing a data output signal WL. The address decoding circuit  30  further comprises a plurality of further logic gates  10   b ,  10   c  and the Wired-OR circuitry  32 . Each of the further logic gates  10   b ,  10   c  corresponds to the logic gate  10  as described in  FIG. 1 . While having a same enabling input  18  for receiving an enabling signal “enable” each of the further logic gates comprises an individual logic tree input  19   b ,  19   c  for receiving N logic inputs and an individual output  20   b ,  20   c  for providing a plurality of further data output signals WL 2 , WL 3 . 
     The Wired-OR circuitry  32  comprises a Wired-OR node “wiredOR”, a supply transistor P WO , an output transistor P WO1  associated with the logic gate  10  and a plurality of further output transistors P WO2 , P WO3  associated with a respective further logic gate  10   b ,  10   c . A control terminal of the output transistor P WO1  is connected to the output  20  of the logic gate  10 . Control terminals of the further output transistors P WO2 , P WO3  are connected to the outputs  20   b ,  20   c  of the respective further logic gates  10   b ,  10   c . A first channel terminal of the output transistor P WO1  is connected to the reference node REF and a second channel terminal of the output transistor P WO1  is connected to the Wired-OR node “wiredOr”. First channel terminals of the further output transistors P WO2 , P WO3  are connected to the reference node REF and second channel terminals of the further output transistors P WO2 , P WO3  are connected to the Wired-OR node. 
     The supply transistor P WO  is controlled by a supply control signal “wopq” at its control terminal. The supply transistor P WO  is connected between the supply node VDD and the Wired-OR node “wiredOR”. 
     While the supply transistor P WO  may be shared between different logic gates  10 ,  10   b ,  10   c  a respective output transistor P WO1 , P WO2 , P WO3  will be used for each logic gate  10 ,  10   b ,  10   c.    
     A condition for the switching-on (closing) of the switching transistor P PD  by the switching control signal “pden” may be derived from the signal at the Wired-OR node “wiredOr” which is denoted by “Rdy” in  FIG. 2 . The logic gate  10  may be applied in any type of address decoding circuit  30  because the point at time in which the switching control signal “pden” is reset to the state 0 can be determined in a particularly simple way here. Since an address decoder  30  typically works in a “one-hot” arrangement, only one of the address decoder cells  10 ,  10   b ,  10   c  changes its state. The outputs  20 ,  20   b ,  20   c  of the cells  10 ,  10   b ,  10   c  may be linked by means of a “Wired-OR” connection. A “Wired-OR” connection connects different outputs  20 ,  20   b ,  20   c  in a direct way without wasting resources to save power. If the common node “wiredOr” has changed its state, the switching control signal “pden” can safely be placed into the state 0 again. The state of the node “wiredOr” is evaluated and has direct influence on the switching control signal “pden”. Here, the supply transistor P WO  is implemented only once for the entire address decoder  30 . 
       FIG. 3   a  shows a logic circuit  40  comprising logic gates and a reference path for generating a switching control signal for the logic gates according to an exemplary embodiment. The logic circuit  40  comprises a dynamic logic stage  42  and a dummy (reference) path stage  44  which are connected in parallel. The dummy path stage  44  comprises a static logic sub-circuit  46  and a dynamic logic sub-circuit  48 . 
     The dynamic logic stage  42  comprises two dynamic logic OR gates DOR 1  and DOR 2  and two dynamic logic AND gates DAND 2  and DAND 3 . The two dynamic logic OR gates and the two dynamic logic AND gates may represent logic gates  10 , according to the logic gate  10  as depicted in  FIG. 1   a . The two dynamic logic OR/AND gates are arranged in propagation groups  51 ,  52 ,  53  with respect to signal propagation times which input signals of respective dynamic logic OR/AND gates experience when propagating through the dynamic logic stage  42 . The first dynamic logic OR gate DOR 1  is associated with the first propagation group  51 . The second dynamic logic OR gate DOR 2  and the first dynamic logic AND gate DAND 2  are associated with the second propagation group  52 . The second dynamic logic AND gate DAND 3  is associated with the third propagation group  53 . 
     A first propagation signal  61  which may correspond to one of the N logic inputs at the logic tree input  19  as depicted in  FIG. 1  is provided at both inputs of the first dynamic logic OR gate DOR 1 , at the first input of the second dynamic logic OR gate DOR 2  and at the second input of the first dynamic logic AND gate DAND 2 . A second propagation signal  62  is provided at the output of the first dynamic logic OR gate DOR 1  which is connected to the second input of the second dynamic logic OR gate DOR 2  and to the first input of the first dynamic logic AND gate DAND 2 . A third propagation signal  63   a  is provided at the output of the second dynamic logic OR gate DOR 2  which is connected to the first input of the second dynamic logic AND gate DAND 3 . A fourth propagation signal  63   b  is provided at the output of the first dynamic logic AND gate DAND 2  which is connected via an inverter INV to the second input of the second dynamic logic AND gate DAND 3 . A fifth propagation signal  64  is provided at the output of the second dynamic logic AND gate DAND 3 . 
     According to propagation times of their input signals the dynamic logic OR/AND gates are associated to propagation groups. As the first dynamic logic OR gate DOR 1  has only the first propagation signal  61  as input it is associated with the first propagation group  51 . The second dynamic logic OR gate DOR 2  and the first dynamic logic AND gate DAND 2  have beside the first propagation signal  61  additionally the second propagation signal  62  as input. The second propagation signal  62  has the additional signal propagation time of the first dynamic logic OR gate DOR 1  with respect to the first propagation signal  61 . Therefore, the second dynamic logic OR gate DOR 2  and the first dynamic logic AND gate DAND 2  are associated with the second propagation group  52 . The second dynamic logic AND gate DAND 3  has the propagation signals  63   a ,  63   b  as inputs which are related to signal propagation times of the first propagation signal  61  propagating through the first dynamic logic OR gate DOR 1  and the second dynamic logic OR gate DOR 2  or the first dynamic logic AND gate DAND 2 , respectively. The second dynamic logic AND gate DAND 3  is associated with the third propagation group  53 . 
     DOR 1  is enabled by the enabling signal “enable_ 1 ”, its switching transistor is controlled by the switching control signal “pden_ 1 ”. DOR 2  and DAND 2  are enabled by the enabling signal “enable_ 2 ”, their switching transistors are controlled by the switching control signal “pden_ 2 ”. DAND 3  is enabled by the enabling signal “enable_ 3 ”, its switching transistor is controlled by the switching control signal “pden_ 3 ”. 
     The dynamic logic sub-circuit  48  comprises three dummy dynamic logic OR gates DOR 1   d , DOR 2   d , DOR 3   d  which are arranged in dummy propagation groups  51   d ,  52   d  and  53   d  associated with the propagation groups  51 ,  52  and  53  of the dynamic logic stage  42 . Each of the dummy dynamic logic OR gates arranged in a respective dummy propagation group has a similar or identical signal propagation delay as the dynamic logic OR/AND gate of the propagation group the respective dummy propagation group is associated with. 
     A first dummy dynamic logic OR gate DOR 1   d  is arranged in the first dummy propagation group  51   d  and receives the first propagation signal  61  at its first and second input. A second dummy dynamic logic OR gate DOR 2   d  is arranged in the second dummy propagation group  52   d  and is connected with its both inputs to the output of the first dummy dynamic logic OR gate DOR 1   d . A third dummy dynamic logic OR gate DOR 3   d  is arranged in the third dummy propagation group  53   d  and is connected with its both inputs to the output of the second dummy dynamic logic OR gate DOR 2   d.    
     The output signal  62   d  of DOR 1   d  has a similar propagation delay as the second propagation signal  62 . The output signal  63   d  of DOR 2   d  has a similar propagation delay as the third or fourth propagation signals  63   a ,  63   b . The output signal  64   d  of DOR 3   d  has a similar propagation delay as the fifth propagation signal  64 . 
     DOR 1   d  is enabled by a first dummy enabling signal “enableDummy_ 1 ”. DOR 2   d  is enabled by a second dummy enabling signal “enableDummy_ 2 ”. DOR 3   d  is enabled by a third dummy enabling signal “enableDummy_ 3 ”. 
     The static logic sub-circuit  46  is used to combine the output signals and associated enabling signals of the dummy dynamic logic OR gates DOR 1   d , DOR 2   d  and DOR 3   d  to provide switching control signals “pden 1 ”, “pden 2 ”, and “pden 3 ” to the dynamic logic OR gates DOR 1 , DOR 2  and dynamic logic AND gates DAND 2  and DAND 3 . 
     The static logic sub-circuit  46  comprises three static logic AND gates. A first static logic AND gate AND 1  combines the inverted output signal  62   d  of DOR 1   d  and the first dummy enabling signal “enableDummy_ 1 ” by a logical AND combination to provide the first switching control signal “pden_ 1 ”. A second static logic AND gate AND 2  combines the inverted output signal  63   d  of DOR 2   d  and the second dummy enabling signal “enableDummy_ 2 ” by a logical AND combination to provide the second switching control signal “pden_ 2 ”. A third static logic AND gate AND 3  combines the inverted output signal  64   d  of DOR 3   d  and the third dummy enabling signal “enableDummy_ 3 ” by a logical AND combination to provide the third switching control signal “pden_ 3 ”. 
     The switching control signals “pden_ 1 ”, “pden_ 2 ” and “pden_ 3 ” are provided by a logic circuitry (dummy path stage  44 ) representing a reference circuit for the dynamic logic stage  42 . By this circuitry it can be assured that the respective switching control signals have an adequate timing with respect to signal propagation delay of the dynamic logic gates DOR 1 , DOR 2 , DAND 2  and DAND 3 . 
     For a greater number of combinational paths, the reference path  44  or dummy path, respectively setting the point in time at which the switching control signal “pden” is to be switched off in individual propagation groups  51 ,  52 ,  53  may be constructed. So, as to achieve better temporal behaviour the reference path  44  could operate in a slightly phase-shifted manner. 
     The dynamic logic OR gates DOR 1 , DOR 2  and the dynamic logic AND gates DAND 2 , DAND 3  of the dynamic logic stage  42  are examples illustrating the functionality of a logic gate  10  as depicted in  FIG. 1   a . Instead of a dynamic logic OR/AND gate also any other type of logic combinational element can be used. The dynamic logic OR gates DOR 1   d , DOR 2   d , DOR 3   d  of the dynamic logic sub-circuit  48  are dimensioned to comprise similar signal propagation times as the dynamic logic gates of the dynamic logic stage  42 . The output signals  62   d ,  63   d ,  64   d  of the dummy dynamic logic OR gates DOR 1   d , DOR 2   d , DOR 3   d  are configured to change their signal state responsive to a transition of the respective dummy enabling signal from a logical 0 to a logical 1. The respective dummy enabling signals may be coupled to the respective enabling signals such that a signal transition of the respective enabling signal triggers a signal transition of the respective dummy enabling signal. 
       FIG. 3   b  shows a set of timing diagrams of signals associated with the logic circuit  40  as depicted in  FIG. 3   a  according to an exemplary embodiment. The timing diagrams depicted in  FIG. 3   b  are one possible implementation for dimensioning the logic circuit  40  as depicted in  FIG. 3   a . In this embodiment, the input signal  61 , the first enabling signal “enable_ 1 ” and the first dummy enabling signal “enableDummy_ 1 ” are synchronized with respect to their rising and falling signal edges. In this embodiment all three signals are (nearly) equal. 
     A second timing diagram ( 2 .) depicts the timing of the input signals  62 ,  62   d , the second enabling signal “enable_ 2 ” and the second dummy enabling signal “enableDummy_ 2 ”. These four signals have a synchronized timing and are delayed by a time delay D 1  with respect to the input signal  61 , the first enabling signal and the first dummy enabling signal. The time delay D 1  results from the propagation delay of the dynamic OR gate DOR 1  or from the propagation delay of the dynamic OR gate DOR 1   d , which is designed to have a similar propagation delay as the dynamic OR gate DOR 1 . 
     The third timing diagram ( 3 .) depicts the timing of the first switching control signal “pden 1 ” which is derived from the first dummy enabling signal “enableDummy_ 1 ” and the inverse of the input signal  62   d  by a logical AND combination. The first switching control signal “pden 1 ” is synchronized to the input signal  61  and the first enabling signal “enable_ 1 ” such that a transition of the first enabling signal from a logical 0 “VREF” to a logical 1 “VDD” controls the switching transistor P PD  of the first dynamic OR gate DOR 1  to provide for an accelerated charge transition of the respective logic node  22 . 
     The fourth timing diagram ( 4 .) depicts the timing of the input signals  63   a ,  63   b ,  63   d , the third enabling signal “enable_ 3 ” and the third dummy enabling signal “enableDummy_ 3 ”. These signals are synchronized with respect to their rising and falling edges and are delayed by a second time delay D 2  with respect to the input signal  62  and the second enabling signal “enable_ 2 ”. The second time delay D 2  corresponds to the propagation delay of the second dummy dynamic OR gate DOR 2   d  which is dimensioned such that it has a similar propagation delay corresponding to the second dynamic OR gate DOR 2  or the first dynamic AND gate DAND 2 , respectively. 
     The fifth timing diagram ( 5 .) depicts the timing of the second switching control signal “pden 2 ” which corresponds to a logical AND combination of the second dummy enabling signal “enableDummy_ 2 ” and the inverse of the input signal  63   d  of the third dummy dynamic OR gate DOR 3   d . The second switching control signal “pden 2 ” is synchronized to the second enabling signal “enable_ 2 ” and is dimensioned such that the switching transistor P PD  of the second dynamic OR gate DOR 2  and the first dynamic AND gate DAND 2  are controlled to provide for an accelerated charge transition of their respective logic nodes  22 . 
     A sixth timing diagram ( 6 .) shows a timing of the output signals  64 ,  64   d  of the third dummy dynamic OR gate DOR 3   d  and the second dynamic AND gate DAND 3 , respectively. Both signals are synchronized with respect to their rising and falling signal edges and are delayed by a time delay D 3  with respect to the third enabling signal “enable_ 3 ” and the input signals  63   a ,  63   b ,  63   d  of DAND 3  and DOR 3   d , respectively. The third time delay D 3  corresponds to a propagation delay of the third dummy dynamic OR gate DOR 3   d  which is dimensioned to be similar to the signal propagation delay of the second dynamic AND gate DAND 3 . 
     The seventh timing diagram ( 7 .) shows the timing of the third switching control signal “pden 3 ” which corresponds to a logical AND combination of the third dummy enabling signal “enableDummy_ 3 ” and the inverse of the output signal “output  64   d ” of the third dummy dynamic logic OR gate DOR 3   d . The third switching control signal “pden 3 ” is synchronized to the third enabling signal “enable_ 3 ” and the input signals  63   a ,  63   b ,  63   d  of DAND 3  and DOR 3   d , respectively, to provide for an accelerated charge transition of their respective logic nodes  22 . 
       FIG. 4   a  shows a circuit diagram of the logic gate  10  as depicted in  FIG. 1   a , wherein the N-block  12  comprises a dynamic logic AND gate according to an exemplary embodiment. The pull down network  12   a  of the logic gate  10   a  comprises a dynamic logic AND gate which is implemented as a series connection of two n-channel transistors N 0  and N 1 , connected between the logic node  22  and the base transistor N F . The first n-channel transistor N 0  is controlled by a first input signal a 0  and the second n-channel transistor N 1  is controlled by a second input signal a 1 . Both input signals a 0  and a 1  are provided by the logic tree input  19 . 
       FIG. 4   b  shows a circuit diagram of the logic gate  10  as depicted in  FIG. 1   a , wherein the N-block  12  comprises a dynamic logic OR gate according to an exemplary embodiment. The pull down network  12   b  of the logic gate  10   b  comprises a logic OR gate which is implemented as a series-connection of an n-channel compensation transistor N T  and a parallel-connection of a first n-channel transistor N 0  and a second n-channel transistor N 1 . The series-connection is connected between the logic node  22  and the base transistor N F . The compensation transistor N T  is controlled by the enabling signal “enable” and is adapted to compensate differences in the switching times of the first and the second n-channel transistors N 0 , N 1 . The first n-channel transistor N 0  is controlled by a first control signal a 0  and the second n-channel transistor N 1  is controlled by a second control signal a 1 . Both control signals a 0 , a 1  are provided by the logic tree input  19 . 
     The compensation transistor N T  optimizes the performance of the pull down network  12   b  but is not necessarily required. Other embodiments may comprise a pull down network  12   b  without the compensation transistor N T , such that the parallel connection of the first n-channel transistor N 0  and the second n-channel transistor N 1  is connected between the logic node  22  and the base transistor N F . The logic gate  10  may also be implemented using transistors of complementary channel type. The base transistor N F  may be implemented as p-channel transistor, the pull-down network  12  implemented as a pull-up network  12  comprising N p-channel (or optionally n-channel) transistors, the charging transistor P P , the keeping transistor P K  and the switching transistor P PD  implemented as n-channel transistors. The sequence of the N-block  12  and the base transistor N F  may be exchanged.